CN111164480A - Optical fiber connector with key structure and manufacturing method thereof - Google Patents

Abstract

Fiber optic connectors, cable assemblies, and methods of making the same are disclosed. In one embodiment, the optical connector includes a housing and a multi-fiber ferrule. The housing includes a longitudinal passageway between a front portion and a rear portion, and the rear portion of the housing includes a keyed portion and at least one locking feature integrally formed in the rear portion of the housing.

Description

Optical fiber connector with key structure and manufacturing method thereof

Cross Reference to Related Applications

This application claims the benefit of the following applications: U.S. application No. 62/428,212 filed 2016, 30, 11, 30, 2016, 62/428,219 filed 2016, 62/428,224 filed 2016, 11, 30, 2016, 62/428,230 filed 2016, 62/428,234 filed 2016, 11, 30, 62/428,244 filed 2016, U.S. application No. 62/428,252 filed on day 11/30 in 2016, U.S. application No. 62/451,221 filed on day 1/27 in 2017, U.S. application No. 62/451,234 filed on day 1/27 in 2017, U.S. application No. 62/526,011 filed on day 1/28 in 2017, U.S. application No. 62/526,018 filed on day 1/28 in 2017, and U.S. application No. 62/526,195 filed on day 1/28 in 2017, the contents of which are relied upon for the present application and are incorporated herein by reference in their entirety.

Background

The present disclosure relates to fiber optic connectors and methods for manufacturing fiber optic connectors. More particularly, the present disclosure relates to fiber optic connectors having improved or simplified designs and methods of making the same.

Optical fiber is increasingly being used for a variety of applications including, but not limited to, broadband voice, video, and data transmission. As bandwidth demands increase, optical fibers are migrating (such as in the form of optical fibers) to users in outdoor communication networks for applications such as FTTx. To address the need for optical connections in communication networks in outdoor environments, hardened fiber optic connectors have been developed. One of the most commercially successful hardened fiber optic connectors is sold by Corning optical communications LLC in Hike, N.C.

Connectors such as those disclosed in U.S. Pat. nos. 7,090,406 and 7,113,679 (the '406 and' 679 patents).

The connector is a hardened male plug connector for terminating a fiber optic cable and the assembly is configured for optical connection, such as with a complementary receptacle. As used herein, the term "hardened" describes a connector or receptacle port intended for making an environmentally sealed optical connection suitable for outdoor use, and the term "unhardened" describes a connector or receptacle port that is not intended for making an environmentally sealed optical connection, such as the well-known SC connector.

FIGS. 1A-1C are illustrations of a display device having a display panel such as

Prior art depiction of various stages of mating of a preconnectorized cable 1 of a plug connector of a connector with a socket. The receptacle 3 mates the plug connector 5 with a standard SC connector at the second end (not visible in these views) using an adapter sleeve that is used to align the ferrules when mating the plug connector 5 with the non-hardened connector. Protection of the non-hardened connector side of the receptacle is typically achieved by mounting the receptacle 3 through a wall of an enclosure or the like such that the non-hardened end of the receptacle is disposed inside the enclosure for environmental protection of the non-hardened connector. As shown in fig. 1A to 1C, the other end of the receptacle 3 is accessible for receiving a plug connector 5 at the wall of the enclosure. Other applications may mount the receptacle 3 on a bracket or the like inside the enclosure.

The socket 3 allows for example

The hardened connector of the male plug connector and the non-hardened connector, such as the SC connector, make an optical connection between them at a node in the optical network, which typically transitions from an outdoor space to an enclosed and protected space. The socket 3 is described in more detail in us patent No. 6,579,014. The receptacle 3 includes a receptacle housing and an adapter ferrule disposed therein. The receptacle 3 receives a non-hardened connector at a second end, as indicated by the arrow pointing to the left. The socket 3 typically needs to pass through the wall of the closure or at the closureInternally, such as mounted to the side of a customer's premises, disposed in an underground vault or pole for protecting the non-hardened connectors from outside plant deployment.

Network operators face a number of challenges in setting up, deploying, and connecting subscribers to external factory communication networks, such as Fiber To The Home (FTTH) or fiber to the place (FTTx) networks. In addition to the right of way for the communication network, the space for the network operator may be limited and not available on existing poles or in existing vaults for installing equipment. Initially, conventional hardened fiber optic connectors are typically mounted on strong and relatively stiff fiber optic cables, and the unused storage of these fiber optic cables may also occupy limited space or become unsightly when deployed in the air. Furthermore, as outside plant deployments evolve, many network operators desire to pass fiber optic cable assemblies with connectors through existing walls of customer premises and into buildings, or pass fiber optic cable assemblies with connectors through buried conduits. As a result, network operators have become sensitive to the size of fiber optic connectors for these types of deployment applications.

Accordingly, there is an unresolved need for a fiber optic connector that allows for quick and easy deployment and connection in a simple and efficient manner while still being cost effective.

Disclosure of Invention

The present disclosure relates to an optical fiber connector and a method of manufacturing an optical fiber connector as described and referenced in the claims. The disclosed concept allows the compact form factor of the fiber optic connector to be adapted to numerous applications and variations as needed.

One aspect of the present disclosure is directed to an optical fiber connector including a shell and a ferrule including at least one optical fiber core. The housing includes a rear end and a front end, with a longitudinal passageway extending from the rear end to the front end. The housing includes a front portion and a rear portion, wherein the rear portion of the housing includes a keyed portion and at least one locking feature is integrally formed in the rear portion of the housing.

Another aspect of the present disclosure relates to an optical fiber connector including a shell and a ferrule including at least one optical fiber core. The housing includes a rear end and a front end, with a longitudinal passageway extending from the rear end to the front end. The housing includes a front portion and a rear portion, wherein the rear portion of the housing includes a female key and at least one locking feature is integrally formed in the rear portion of the housing.

Yet another aspect of the present disclosure is directed to an optical fiber connector including a shell and a ferrule including at least one optical fiber core. The housing includes a rear end and a front end, with a longitudinal passageway extending from the rear end to the front end. The housing includes a front portion and a rear portion, wherein the rear portion of the housing includes a recessed key and at least one locking feature integrally formed in the rear portion of the housing, and the at least one locking feature is disposed about 180 degrees from the recessed key.

Yet another aspect of the present disclosure is directed to an optical fiber connector including a shell and a ferrule including at least one optical fiber core. The housing includes a rear end and a front end, with a longitudinal passageway extending from the rear end to the front end. The housing includes a front portion, a rear portion, and a transition region disposed between the front portion and the rear portion of the housing, wherein the rear portion of the housing includes a keyed portion extending into a portion of the transition region and at least one locking feature integrally formed in the rear portion of the housing, and the at least one locking feature is disposed about 180 degrees from the keyed portion.

Another aspect of the present disclosure relates to an optical fiber connector including a shell and a ferrule including at least one optical fiber core. The housing includes a rear end and a front end, with a longitudinal passageway extending from the rear end to the front end. The housing includes a front portion, a rear portion, and a transition region disposed between the front portion and the rear portion of the housing, wherein the rear portion of the housing includes a recessed key extending into a portion of the transition region and at least one locking feature integrally formed in the rear portion of the housing, the transition region includes a threaded portion and the at least one locking feature is disposed about 180 degrees from the recessed key.

Another aspect of the present disclosure relates to a fiber optic connector including a housing, a ferrule including at least one fiber bore, a cable adapter, a boot attached to the cable adapter, and a sealing element. The housing includes a rear end and a front end, wherein a longitudinal passageway extends from the rear end to the front end, and the rear end includes a rear opening. The cable adapter is sized to fit into the rear opening of the housing and the sealing element is disposed about a portion of the boot and a portion of the rear portion of the housing.

Additional features and advantages will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art from that description or recognized by practicing the embodiments described herein, including the detailed description which follows, the claims, as well as the appended drawings.

It is to be understood that both the foregoing general description and the following detailed description present an overview or framework intended to provide an understanding of the nature and character of the claims. The accompanying drawings are included to provide a further understanding of the disclosure, and are incorporated into and constitute a part of this specification. The drawings illustrate various embodiments and together with the description serve to explain the principles and operations.

Drawings

Fig. 1A-1C are prior art depictions showing various stages of mating of a prior art preconnectorized cable with a conventional hardened plug connector with a receptacle;

FIG. 2 is a perspective view of a fiber optic cable assembly having a fiber optic connector with a jacket according to one aspect of the present disclosure;

FIG. 2A is a perspective view of another fiber optic cable assembly having a fiber optic connector with a keyed portion according to one aspect of the present disclosure;

FIG. 3 is an exploded view of the fiber optic cable assembly of FIG. 2;

FIG. 4 is a close-up perspective view of a fiber optic connector having a housing similar to that of FIG. 2 and depicting geometric features of the housing, according to one aspect of the present disclosure;

FIGS. 4A-4D are respective cross-sectional views of the housing of FIG. 4 taken along respective planes defined by line 4A-4A, line 4B-4B, line 4C-4C, and line 4D-4D;

FIG. 4E is a side view of an exemplary housing similar to that shown in the fiber optic connector of FIG. 4 and further including discontinuous threads on a front portion;

FIG. 5 is an exploded view of a ferrule subassembly of the fiber optic connector of FIG. 3;

fig. 6 and 7 are longitudinal cross-sectional views of the ferrule assembly cable assembly of fig. 3;

FIG. 8 is a perspective view of the ferrule carrier of the ferrule subassembly of FIG. 3;

FIG. 9 is a close-up perspective view of the front end of the ferrule subassembly of FIG. 8;

fig. 10 is a perspective view of an alternative ferrule carrier that may be used with the ferrule assembly disclosed herein;

fig. 11 and 12 are a partially exploded view and an assembled view, respectively, of the alternative ferrule carrier depicted in fig. 10;

fig. 13 and 14 are partial cross-sectional and cross-sectional views, respectively, of the alternative ferrule carrier of fig. 10-12 depicted in a housing of an assembled fiber optic connector;

FIGS. 15 and 16 are longitudinal cross-sectional views of the fiber optic cable assembly of FIG. 2 showing details of construction;

FIG. 17 is an exploded view of another fiber optic cable assembly similar to the fiber optic cable assembly of FIG. 2 having fiber optic connectors of a different ferrule assembly;

FIG. 18 is a partial exploded view of the fiber optic cable assembly of FIG. 17 with the fiber optic cable attached to the ferrule assembly;

FIG. 19 is a perspective view of another cable assembly having a different fiber optic connector with a housing similar to that shown with the fiber optic connector of FIG. 2 according to another aspect of the present disclosure;

FIG. 20 is a close-up perspective view of the fiber optic connector of FIG. 19 depicting geometric features of the housing;

FIG. 21 is an exploded view of another fiber optic cable assembly similar to the fiber optic cable assembly of FIG. 19 having a fiber optic connector with a discontinuous threaded housing according to another aspect of the present disclosure;

FIG. 22 is an exploded perspective view of the fiber optic cable assembly of FIG. 21;

FIG. 23 is a perspective view of the cable assembly of FIG. 22 with the fiber optic connector mounted thereon;

FIG. 24 is a longitudinal cross-sectional view of the cable assembly of FIG. 22 in a vertical orientation;

FIG. 25 is a detailed exploded view of the front end of the fiber optic connector of FIG. 22;

FIG. 26 is a cross-sectional view taken at the opening of the housing and showing a transverse ferrule retention member securing the ferrule of the fiber optic connector of FIG. 22;

fig. 27 and 28 are a detailed view and a cross-sectional view, respectively, showing an alternative lateral ferrule retention member for securing a ferrule;

FIG. 29 is a longitudinal cross-sectional view of the front portion of the fiber optic connector of FIG. 22 in a horizontal orientation;

FIG. 30 is a front cross-sectional view of a housing with adjustment pockets that allow for rotational adjustment of the ferrule during manufacture for improved optical performance;

fig. 31 and 32 depict an exemplary ferrule having at least one selectively adjustable surface;

fig. 33-36 are various views depicting the housing of the fiber optic connector of fig. 23;

FIG. 37 is a perspective view of another fiber optic cable assembly having yet another alternative fiber optic connector with a ferrule;

FIG. 38 is a perspective view of the fiber optic cable assembly of FIG. 37 showing a perspective view of a dust cap having a pull hole and securable to threads provided on the housing;

FIG. 39 is an exploded view of the cable assembly of FIG. 37;

FIG. 40 is a front cross-sectional view of the fiber optic connector of FIG. 37 showing the nosepiece attached to the front end of the housing;

FIG. 41 is a front end view of the shell of FIG. 37 showing a securing surface, such as a weld interface, located on the shell such that the nozzle may be attached to the shell such that it changes the opening of the lateral ferrule retention member;

FIGS. 42 and 43 are perspective and side views of a fiber optic connector similar to FIG. 37 having an alternative housing with keying features of the fiber optic connector;

FIGS. 44 and 45 are perspective views of alternative housings depicting other locking feature designs for use with the disclosed fiber optic connectors;

FIG. 46 is a perspective view of another fiber optic cable assembly having a cable adapter that fits into the rear opening of the housing, which can vary for different types of fiber optic cables;

fig. 47 and 48 are perspective and cross-sectional views, respectively, of the cable adapter of fig. 46;

FIGS. 47A and 48A are perspective and cross-sectional views, respectively, of another cable adapter;

FIG. 49 is a cross-sectional view of a rear portion of an exemplary fiber optic cable assembly showing a fiber optic cable cut in a vertical direction within a cable adapter depicting the manner in which electrical circuitry may be attached to the fiber optic connectors disclosed herein;

FIG. 50 is a cross-sectional view of a rear portion of the cable assembly of FIG. 46 showing the fiber optic cable within the cable adapter taken in a horizontal direction;

FIGS. 51-54 are various views of another fiber optic cable assembly having a keying portion configured as a female key; FIGS. 51A-53A are various views of a portion of another fiber optic cable assembly having a cable adapter with a flexure for cable bending stress relief;

FIG. 54A is a front perspective view of another housing that can be used with the fiber optic connector concepts disclosed herein.

FIG. 55 depicts a distribution cable having fiber optic connectors disposed on a tether cable according to the disclosed concepts;

FIG. 56 is a perspective view of an exemplary fiber optic connector further including a transition housing attached about the housing for changing the fiber optic connector from a first connector footprint to a second connector footprint;

FIG. 57 is a cross-sectional view of the fiber optic connector of FIG. 56;

FIG. 58 is a partial exploded view of an exemplary fiber optic connector showing a fiber optic connector having a first connector footprint and a conversion housing for changing the fiber optic connector to a second connector footprint, which is a hardened connector footprint;

FIG. 59 is an assembled view of the fiber optic connector of FIG. 58 showing the second connector footprint as a hardened connector footprint with the dust cap removed for clarity;

FIG. 60 is an assembled view of the fiber optic connector of FIG. 58, showing a second connector footprint with a dust cap installed;

fig. 61 is a cross-sectional view of the fiber optic connector of fig. 60.

FIG. 62 is a perspective view of an exemplary fiber optic connector that can have a transition housing attached around the housing for changing the fiber optic connector from a first connector footprint to a second connector footprint;

FIG. 63 is an assembled view of the fiber optic connector of FIG. 62 in a converted to a second connector footprint configured to harden the connector footprint, with the dust cap removed for clarity;

FIG. 64 is a partially exploded view of the fiber optic connector of FIG. 63;

FIG. 65 is a cross-sectional view of the transition housing and coupling nut of the fiber optic connector of FIG. 63;

fig. 66 and 67 are cross-sectional views of the fiber optic connector of fig. 63;

FIGS. 68 and 69 are perspective views of a retaining member of the fiber optic connector of FIG. 63;

fig. 70 and 71 are perspective and cross-sectional views, respectively, of another connector having a ferrule loaded from the front end of the connector 10 and with an SC shell attached, disposed within a ferrule holder;

fig. 72 is a perspective view of the connector housing of fig. 70 and 71;

fig. 73 and 74 are cross-sectional views of the housing of the connector of fig. 70 and 71;

fig. 75 is a partial exploded view of the front end of the connector depicted in fig. 70 and 71;

fig. 76 is a cross-sectional view of the front end of the connector depicted in fig. 70 and 71;

FIG. 77 is a perspective view of a ferrule and ferrule holder of the connector depicted in FIGS. 70 and 71;

FIG. 78 is a front end view of the connector depicted in FIGS. 70 and 71 without the SC housing, showing details of retention for the ferrule holder assembly;

FIG. 79 is an assembled perspective view of a cable assembly including a multi-fiber connector including a housing with a transition region having a threaded portion;

FIG. 80 is a perspective view of the multi-fiber connector of FIG. 79 with a dust cap attached;

FIG. 81 is an exploded view of a cable assembly having the multi-fiber connector of FIG. 79;

FIGS. 82 and 83 are detailed exploded and assembled views, respectively, showing the pre-assembly of the multi-fiber connector of FIG. 79 prior to threaded connection of the fiber optic cable by pre-assembly of its components;

FIG. 84 is a perspective view of a fiber optic cable ready for insertion into the preassembly of FIG. 83;

FIGS. 85 and 86 are perspective and cross-sectional views, respectively, of the fiber optic cable through the pre-assembled threaded connection of FIG. 83;

FIG. 87 depicts a perspective view of the assembly of FIG. 83 after removal of a portion of the coating of the optical fibers in preparation for insertion of the ends of the optical fibers into a multi-fiber ferrule;

FIGS. 88 and 89 are perspective and cross-sectional views, respectively, of a multi-fiber ferrule attached to optical fibers of a fiber optic cable;

FIG. 90 shows the housing of the connector prior to being attached to a cable adapter of a multi-fiber connector;

fig. 91 and 92 show perspective and cross-sectional views, respectively, of a housing of a multi-fiber connector prior to being attached to a cable adapter; and is

Fig. 93 depicts a perspective view of the assembled multi-fiber connector after the ferrule is attached; and is

Fig. 94 and 94A are perspective and cross-sectional views, respectively, of another connector housing including a non-circular rear portion.

Detailed Description

Reference will now be made in detail to embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used to refer to the same parts or features.

The disclosed concept advantageously provides fiber optic connectors that enable streamlined manufacturing and assembly and simple intuitive connections with other devices while still having a compact footprint. The disclosed fiber optic connectors are illustrated and described by a number of different embodiments and various other alternative components or optional features that may be incorporated as desired into one or more of the concepts of fiber optic connectors having keyed portions. By way of illustration, several different variations of a shell are disclosed that can be modified for use with a connector configuration in which a ferrule is loaded from a back end of the shell or a ferrule is loaded from a front end of the shell. Some embodiments may advantageously use fewer parts while providing robust and reliable optical performance. For example, some of the disclosed embodiments may mate (e.g., assemble) a ferrule directly with a housing without using a ferrule holder as with conventional fiber optic connectors. Other configurations may increase the part count of the connector for various reasons or may use a ferrule holder as desired.

In one aspect, the disclosed fiber optic connectors (hereinafter "connectors") advantageously include a housing having a rear portion that includes a keyed portion and a ferrule. The housing provides a first connector footprint that interfaces with other devices for making optical connections, and various different first connector footprints that may be used with the disclosed connector configurations are disclosed herein. The first connector footprint may be defined by a housing having a Rear Portion (RP) with a keyed portion and a Front Portion (FP). The first connector footprint may be further defined by a Transition Region (TR) disposed between the Rear Portion (RP) and the Front Portion (FP) of the housing.

In one illustrative example, the housing includes a portion having a circular cross-section (RCS) including a Rear Portion (RP) having a keyed portion and a portion having a non-circular cross-section (NRCS) including a front portion. The Front Portion (FP) or the Rear Portion (RP) of the housing may also be defined in various configurations as disclosed herein while maintaining a portion of the Rear Portion (RP) having a circular cross-section (RCS) and a portion of the Front Portion (FP) having a non-circular cross-section (NRCS). Illustratively, the Rear Portion (RP) includes a keyed portion and the Front Portion (FP) may have a rectangular cross-section that also provides the connector with a first orientation feature for aligning and preventing insertion into a non-compliant device or port during mating. The keying portion of the connector mates with a key on a complementary port to prevent damage to the port by preventing insertion of a non-compliant connector. The keying portion may also assist the user in determining the correct rotational orientation during blind insertion of the connector into the port when line of sight is not possible or practical.

However, other variations of the housing in accordance with the disclosed concept are also possible. As an example of another housing disclosed herein for use with the disclosed connector configuration, the housing may be defined as including a portion of a Rear Portion (RP) having a polygonal cross-section (PCS) and a portion of a front portion having a non-circular cross-section (NRCS). The Front Portion (FP) or Rear Portion (RP) of this example housing may also be defined in various configurations as disclosed herein while maintaining a portion of the Rear Portion (RP) having a polygonal cross-section (PCS) and a portion of the Front Portion (FP) having a non-circular cross-section (NRCS), such as shown in fig. 79 and 79A. As examples, the polygonal cross-section (PCS) may be hexagonal, square, or any other suitable polygon as desired.

The housings disclosed herein define mating interfaces of complementary devices adapted to mate with connectors, and the disclosed connector footprints may be used to prevent insertion into and damage to a non-compliant port or device and to ensure proper optical operation of an optical connection since the connector is mated with the device. However, the housing may have features (such as markings, keys, keyways, etc.) that facilitate proper alignment or orientation of the connector with the complementary device without significantly altering the original form factor of the housing disclosed and claimed herein. By way of example, a circular cross-section is considered to be a circular cross-section even though it may include another feature, such as a key or keyway. In addition, the housing may have other features, such as locking features for securing an optical fit with a complementary device or threads for securing a dust cap. The locking feature may provide a predetermined retention force of 50 pounds or more by the complementary means.

The housing footprints disclosed herein may be further defined by other geometries of one or more housings. As an example, the Transition Region (TR) is arranged between the Rear Portion (RP) and the Front Portion (FP). The Transition Region (TR) may have different configurations in accordance with the disclosed concept. In one embodiment, the Transition Region (TR) may include a first transition portion (TP1) disposed on a first side of the housing and a second transition portion (TP2) disposed on a second side of the housing. The first transition portion (TP1) and the second transition portion (TP2) may be spaced apart by an Offset Distance (OD) in the longitudinal direction. However, other embodiments of the housings disclosed herein may align all transition portions of the Transition Region (TR) along a common transverse plane of the connector, as desired. In other embodiments, the Transition Region (TR) of the housing may include a Threaded Portion (TP).

Other variations may further define the housing footprint disclosed herein. As an example and illustration for use with a suitable enclosure as disclosed, the first transition portion (TP1) comprises a First Riser Dimension (FRD) from the non-circular cross-section (NRCS) to the circular cross-section (RCS), and the second transition portion (TP2) comprises a Second Riser Dimension (SRD) from the non-circular cross-section (NRCS) to the circular cross-section (RCS), wherein the First Riser Dimension (FRD) is different from the Second Riser Dimension (SRD).

As another example of a non-circular cross-section (NRCS) for use with suitable housings disclosed herein, a portion of the Front Portion (FP) of the housing having the non-circular cross-section (NRCS) includes having Rounded Corners (RC). A rectangular cross section with Rounded Corners (RC) becomes a non-circular cross section (NRCS) due to the rectangular cross section. The Rounded Corners (RC) may be sized such that they have an Outside Dimension (OD) that is similar or dissimilar to the dimension (D) of the rounded cross-Section (RCs). The Rounded Corners (RC) may provide stability and snug fit of the mated connector within the port or device when subjected to side pulling forces to prevent undue optical attenuation by transitioning the rounded corners between the Front Portion (FP) to the back portion (RP). However, other geometries are possible, such as chamfers or the like when the Rear Portion (RP) has a polygonal cross-section (PCS).

The housing footprints disclosed herein may be further defined by other geometries of one or more housings. For example, the Front Portion (FP) of the housing may comprise a further cutaway portion (ACSP). Illustratively, another cross-sectional portion (ACSP) may include an SC footprint. The SC footprint may be partially similar to the inner housing of a conventional SC connector. This particular housing footprint may be used to allow the disclosed connector to be backward compatible into existing devices or ports as needed using a well established connector footprint.

The housing may also define other features, such as a transition region disposed between the posterior portion and the anterior portion, wherein the transition region includes a transition that is asymmetric with respect to a longitudinal axis of the housing. Likewise, other features on the housing may define the housing as asymmetric for orientation or mating with a compliant device or port.

Another aspect of some of the advantageous connectors disclosed herein includes one or more features that allow the ferrule to be rotated during assembly for adjusting the connector and improving optical performance. Some of the disclosed connector designs also provide multi-stage or infinite adjustment of the ferrule/assembly to any desired rotational position for improved optical performance.

The concepts disclosed herein are suitable for manufacturing both indoor and outdoor fiber optic cable assemblies, such as drop cables or distribution cables, using the disclosed connectors. Further, the disclosed fiber optic connectors may allow for the use of one or moreAdditional components to alter the form factor of the connector defined by a particular housing. As an example, the conversion housing is mateable with a housing of the connector for changing the fiber optic connector from a first connector footprint defined by the housing to a second connector footprint at least partially defined by the conversion housing. Thus, the connector disclosed herein may be converted to other well-known commercial connectors for fiber to the home applications (such as SC connectors or such as are available from Commingoptical Communications in Hickia, N.C.)

Connectors) are compatible. Of course, the concepts disclosed herein may be used with other fiber optic connector types, whether hardened or not, and are not limited to these particular connector transitions. Also, the disclosed connector design may be a hybrid design with both optical and electrical connections. Electrical connections may be provided through contacts on or in a portion of the housing of the connector and may be for power or data as needed for applications such as FTTx, 5G, industrial applications, and the like. These and other concepts are discussed and disclosed herein in illustrative detail with reference to the figures.

Several different configurations of fiber optic cable assemblies 100 (hereinafter "cable assemblies") including connectors 10 and variations of connectors 10 are disclosed herein. The connector 10 may use any suitable housing or different connector configuration as desired and appropriate. By way of illustration, fig. 2, 2A, 3, and 5-17 disclose a connector in which the ferrule 30 is inserted from the rear end 21 of the housing 20, and fig. 19-43 and 46-53 disclose a connector in which the ferrule 30 is inserted from the front end 23 of the connector 10. Fig. 2A is a representative housing according to the concept, which shows a key portion 20KP provided in a rear portion RP of the housing 20. As shown, the keyed portion 20KP is a cut-back keyed portion from the original geometric circular shape, such as a recessed key (not labeled) or a keyway as shown in fig. 2A. However, the concept of the housing 20 may be modified for use with the disclosed connector concept and not all of the relieved keying portion need be keyways. For example, the keyed portion 20KP may be defined as a cutout from a portion of the rear portion RP of the housing 20, such as by cutting the sides flat, thereby providing a generally D-shaped cross-section to a portion of the rear portion RP of the housing 20.

Fig. 4A-4E depict exemplary housings 20 for discussion of geometries that may be generally used with any suitable connector configuration, as well as modifications or alterations to the housings for desired housing designs or connector configurations. As shown, the housing 20 includes a keyway portion 20 KP. Further, the broken line 20 KP' illustrates that the key portion may be formed by cutting a side portion of the housing 20, instead of the key groove shape. The keyway portion 20KP may also extend into the transition region TR. Likewise, the housing 20 of fig. 2A shows a keyed portion having a threaded Transition Portion (TP), and the housing may be modified or altered as desired for other housing designs or connector configurations. For example, the keyed portion 20KP may be used with a key on the front portion of the housing 20. Illustratively, fig. 73 depicts the concept of the convex key 20K used with the key portion 20 KP. In this case, the convex key 20K and the key portion 20KP are aligned in the longitudinal direction of the connector. The concepts disclosed herein may also be used with multi-fiber connectors. Fig. 44 and 45 disclose concepts related to an alternative locking feature 20L that is optionally used with the housing 20. Fig. 46-53 disclose another cable assembly 100 that includes a connector 10 concept that discloses another cable adapter that may be used with suitable connectors 10 disclosed herein. Fig. 54 depicts a connector 10 having another housing footprint in accordance with the disclosed concept. Fig. 56-61 disclose a cable assembly 100 including a connector 10 having a first connector footprint, wherein the connector 10 may be convertible to a connector 10' having a second connector footprint using a conversion housing 80, 82. Fig. 62-69 disclose a cable assembly 100 including a connector 10 having a first connector footprint, wherein the connector 10 may be convertible to a connector 100' having a second connector footprint using a different conversion housing 82. Fig. 70-78 disclose a connector in which a ferrule 30 is disposed within the ferrule holder 49 and inserted from the front end 23 of the connector 10.

Fig. 2 is a perspective view and fig. 3 is an exploded view of a cable assembly 100 having a connector 10 and a fiber optic cable 90 (hereinafter "cable"). Fig. 15 and 16 are longitudinal cross-sectional views of the cable assembly 100 of fig. 2 showing details of construction. Fig. 2A depicts cable assembly 100 having a connector 10 with a housing 20 similar to housing 20 of connector 10 of fig. 2, but housing 20 of fig. 2A has a different transition region TR. Specifically, the housing 20 of fig. 2A has a transition region TR with a threaded portion TP and may be optionally used with the connector configurations disclosed herein.

The connector 10 includes a housing 20 and a ferrule 30. The housing 20 comprises a rear end 21 and a front end 23, wherein the longitudinal passage 22 extends from the rear end 21 to the front end 23. As best shown in fig. 7, ferrule 30 includes a fiber bore 32 extending from a rear end 31 to a front end 33. The passage 22 allows one or more optical fibers of the cable 90 to pass through the housing 20 for insertion into the fiber holes 32 of the ferrule 30, as depicted in fig. 7. Cable 90 includes at least one optical fiber 92, one or more strength members 94, and a cable jacket 98.

The connector 10 or components of the connector 10 as depicted in fig. 2, 2A, 3, and 5-17 allow the ferrule 30 to be inserted into the housing 20 from the back end 21 of the housing 20. Specifically, the ferrule 30 is inserted into the opening 21A at the rear end 21 of the housing 20. The housing 20 depicted in fig. 2A is similar to the housing 20 of fig. 2, except that it has a different Transition Region (TR). Specifically, the Transition Region (TR) of the housing 20 of fig. 2A includes a threaded portion; additionally, the concept of a connector is similar to other concepts disclosed herein. The threaded portion (TR) allows for the securing of a suitable dust cap 70 and also allows for a connector footprint such as a hardened connector footprint as shown in fig. 62-69. However, the concept of a rear insertion connector configuration may be used with any suitable housing disclosed herein.

As depicted, the connector 10 of fig. 3 includes a housing 20, a ferrule subassembly 60, and a cable adapter 59. In this embodiment, the ferrule 30 is part of a ferrule assembly 60. The opening 21A at the rear end 21 of the housing 20 is sized for receiving a portion of the ferrule tube assembly 60. When assembled, the ferrule tube assembly 60 is configured to cooperate with the housing 20 for preventing rotation of the ferrule tube assembly 60 relative to the housing 20. However, the ferrule-tube assembly 60 may be configured to allow the ferrule 30 to be rotated for adjustment as represented by the arrow and angle θ before the ferrule-tube assembly 60 is fully seated within the housing 20, as discussed herein.

The ferrule tube assembly 60 also includes a ferrule carrier 40. The ferrule carrier 40 may have different configurations, as disclosed herein. The ferrule 30 may be adjusted relative to the housing 20as needed, and may be adjusted in steps in defined increments based on the ferrule geometry. However, other features or designs disclosed herein for the connector may allow for infinite adjustment of the ferrule to any desired rotational position. Adjusting the ferrule 30 achieves improved optical performance by adjusting the ferrule such that any eccentricity in the fiber, ferrule, or connector is rotated in a consistent manner to a known rotational position or quadrant. Accordingly, the connector or other mating device may be adjusted to a similar relative rotational position for improved optical performance, such as reduced optical insertion loss due to fiber core misalignment, etc., as understood in the art. Embodiments disclosed herein may also have multiple interfaces between components for adjusting the connector as needed.

The design of the connector 10 of fig. 3 may also advantageously enable multi-level adjustment as desired. The ferrule 30 or other component/assembly may be capable of adjustment in incremental increments, such as quadrants, or infinitely as desired. As an example, the ferrule-tube assembly 60 may be configured to allow the shaft assembly to rotate as needed relative to the cable adapter 59 (or other component) for arrows and angles as needed

The ferrule 30 is adjusted as shown. Further, the multi-stage adjustment may result in an infinite adjustment, meaning that any desired rotational positioning desired for any eccentricity of the fiber core within the ferrule 30 is possible. The adjustment step or angle at the different component interfaces may depend on the particular configuration of the ferrule, ferrule carrier, cable adapter or housing with respect to the allowable rotation and possible rotational increments of the assembly.

As an example, the first stage of adjustment may be a quadrant-by-quadrant stepped adjustment, while the second stage of adjustment may be an infinite adjustment, enabling infinite rotation, as desired. More specifically, a first step adjustment may be used for a coarse adjustment of the eccentricity of the fiber core, such as to a desired quadrant, and then a second step provides infinite adjustment for precise rotational positioning by enabling fine adjustment of the eccentricity of the optical core within the quadrant. By way of illustration, infinite adjustment may be achieved by rotating one or more components through an angle of ± 180 degrees without incremental steps, allowing for any rotational position of the ferrule 30. Of course, other adjustment schemes are possible using the concepts disclosed herein. Likewise, variations of the ferrule carrier 40 or ferrule assembly 60 are also possible and are disclosed herein for use with any suitable housing 20.

The connector 10 of fig. 3 allows the ferrule 30 to be rotated or adjusted within the ferrule tube assembly 60, as depicted. The ferrule 30 may be configured to rotate in a stepped rotation or an infinite rotation depending on the particular design. For example, the ferrule 30 may have a selectively adjustable surface 36 that is rounded for providing infinite rotational positioning, or the selectively adjustable surface of the ferrule 30 may include a plurality of flat surfaces 36 for step adjustment by allowing only certain rotational positions. Further, infinite adjustment of the ferrule 30 may be accomplished by adjusting or rotating an angle θ of ± 180 degrees relative to the ferrule carrier 40 as desired. The ability to rotate one or more components in either direction allows for adjustment flexibility and prevents the generally undesirable over-twisting of the optical fiber.

The connector 10 of fig. 3 also allows the ferrule carrier 40 to rotate to adjust the ferrule relative to the housing 20, as depicted. In this embodiment, the ferrule carrier 40 can be adjusted relative to the housing 20 by the rotational position of the ferrule carrier 40 relative to the cable adapter 59 or the rotational position of the cable adapter 59 relative to the housing. Specifically, the ferrule carrier 40 may be adjustable at an angle of ± 180 degrees relative to the housing 40

Or adjusted in incremental steps as desired, such as using a ferrule carrier rotation key 41K (fig. 5). For example, the ferrule carrier rear end 41 may have one or more keys for mating with the cable adapter 59 and only allow certain positions for adjustment, or the ferrule carrier rear end 41 may simply mate with the cable adapter 29 for providing an infinite rotational position for adjustment. The details of the adjustment will be discussed in more detail below.

Likewise, the connector 10 of fig. 3 may have a third interface for adjustment. Specifically, the cable adapter 59 may be adjustable relative to the rear end 21 of the housing 20. Like the ferrule carrier rear end 41, a flange portion (not numbered) of the cable adapter 50 can have one or more keys for mating with the rear end 21 of the housing 20 and only allow certain positions for adjustment, or a flange portion of the cable adapter 59 can simply mate with the rear end 21 of the housing 20 for providing an infinite rotational position for adjustment. Thus, the connector 10 of fig. 3 provides several different adjustment options for manufacturing depending on the desired requirements of the connector.

Fig. 4-4E depict an exemplary housing 20 of a connector and will be described in more detail to explain the concepts and geometries of the housing 20 that are suitable for use with the connector concepts disclosed herein. While the housing of fig. 4 is a close-up perspective view of the connector 10 having a different configuration than the housing 20 depicted in fig. 2 and 3, the housing 20 of fig. 4 is similar to the housing 20 of the connector of fig. 2 and 3. In general, the footprint of the shell 20 of fig. 4 may be used with a connector configuration that inserts the ferrule 30 from the back end 21 of the shell 20 or a connector configuration that inserts the ferrule 30 from the front end 23 of the shell with one or more modifications to the connector configuration. Illustratively, the longitudinal passageway 22 of the housing 20 may need to be modified for different connector configurations as appropriate.

The connector 10 disclosed herein may use any suitable housing 20 having a desired footprint or configuration. The present disclosure describes several different housings that may be used with the connector configuration as appropriate, and other variations are possible. Fig. 4 depicts that the housing 20 and connector 10 may use various variations of the housing shown in fig. 4 or other housings such as the housing 20 shown in fig. 54 having locking features on separate components. Likewise, the housing 20 may include one or more features for alignment during mating, and may also include other features for securing or locking the connectors in the appropriate complementary ports or devices. The housing 20 has a relatively compact form factor, such as having a length L of about 40 centimeters (mm) or less and a cross-sectional dimension of about 15mm or less, such as 12mm or less, although other suitable dimensions for the housing are possible.

Fig. 4A-4D are respective cross-sectional views of the housing of fig. 4 taken along respective planes defined by line 4A-4A, line 4B-4B, line 4C-4C, and line 4D-4D. Lines 4B-4B and 4C-4C are taken at the same cross-section. Fig. 4E is a side view of the housing 20, which is similar to the housing 20 shown in fig. 4, but also includes threads 28 of the housing 20as depicted in fig. 3 and 4. The threads 28 are disposed on the front portion FR of the housing 20 and are discontinuous.

The housing 20 includes a rear end 21 and a front end 23, with a longitudinal passageway 22 extending from the rear end 21 to the front end, as shown in fig. 4E. The housing 20 of fig. 4A to 4E comprises a part of the rear portion RP having a circular cross section RCS and a part of the front portion NRCS having a non-circular cross section. The transition region TR is arranged between the rear portion RP and the front portion FP of the housing 20. The transition region TR comprises a first transition portion TP1 arranged on the first side of the housing and a second transition portion TP2 arranged on the second side of the housing. In this version, the first transition portion TP1 and the second transition portion TP2 are spaced apart by an offset distance OD in the longitudinal direction of the housing 20, as best shown in fig. 4E. The offset distance OD of the transition region TP is useful because it allows the connector to be fully seated only into a complementary device or port having a mating geometry. However, other housings 20 of the connectors disclosed herein may omit the offset distance as desired.

Housing 20 may also have suitable features or structures for sealing connector 10. The sealing plane should be located at a suitable position along the housing 20 for providing the appropriate environmental protection required by the desired environment. Illustratively, the housing 20 may include one or more grooves 20G for receiving appropriately sized O-rings 65. The housing 20 may include other features or structures to assist in sealing. For example, housing 20 may have a suitable surface for receiving a portion of heat shrink 99 or the like for sealing between a portion of cable 90 and connector 10. Any suitable heat shrink (such as a glue line heat shrink) may be used. In addition, other structures or features may also be used to assist in providing a robust sealed cable assembly 100.

As used herein, the transition region TR is provided between the rear end 21 and the front end 23 where the housing 20 makes a transition from a portion of the rear portion RP to a portion of the front portion FP in the original cross-sectional shape. As used herein, an original profile means the outer perimeter of the profile without regard to the internal features of the profile. Further, portions of the profile may include other features that modify the shape of the original profile as desired, such as keying, retention, or locking features, while still practicing the transition region TR or forward/rearward portions as disclosed herein. For example, the front portion FP may have rounded or chamfered corners while still being rectangular in cross-section.

In this embodiment of the housing 20, the front portion FP of the housing 20 may have a rectangular cross-section that provides the connector with a first orientation feature for aligning and preventing insertion into a non-compliant device or port during mating. The non-circular cross-section NRCS has a rectangular cross-section with a width W1 and a height H1, as shown in fig. 4B. The rectangular cross-section provides a first orientation feature in that the rectangular portion may only be inserted into a complementary device or port in certain orientations due to its rectangular shape, preventing incorrect insertion into or preventing insertion into a non-compliant device or port.

As best shown in fig. 4C, the housing 20 of fig. 4A-4E has a first transition portion TP1 and a second transition portion TP2, the first transition portion TP1 including a first riser dimension FRD from the non-circular cross-section NRCS to the circular cross-section RCS, and the second transition portion TP2 including a second riser dimension SRD from the non-circular cross-section NRCS to the circular cross-section RCS, wherein the first riser dimension FRD is different than the second riser dimension SRD. Riser dimensions are measured perpendicularly from the midpoint of the strand defined by the surface of the non-circular cross-section NCRS (as shown in fig. 4C) to the outer surface of the circular cross-section RCS.

The geometry of the housing 20 of fig. 4A-4E also includes a non-circular cross-section NRCS that includes a rectangular cross-section with rounded corners RC sized such that they have an outer dimension OD similar to dimension D of the circular cross-section RCs. Rounded Corners (RC) may provide stability and snug fit of the mated connector 10 within the port or device when subjected to side pulling forces to prevent undue optical attenuation by transitioning the rounded corners between the front portion FP to the rear portion RP.

The depicted front portion FP of the housing 20 has more than one original cross-sectional shape over its length. In particular, the front portion FP of the housing 20 of fig. 4 to 4E also comprises a further cutaway portion ACSP. Illustratively, another cross-sectional portion (ACSP) may include an SC footprint. The SC footprint may be partially similar to the inner housing of a conventional SC connector. This particular housing footprint may be used to allow the disclosed connector to be backward compatible into existing devices or ports as needed using a well established connector footprint. Other embodiments may have connectors configured for LC connectors or other known connector footprints as desired.

As best shown in fig. 4 and 4D, the front portion of the housing 20 may include another cross-sectional portion ACSP having an original cross-section that is different than the non-circular cross-section NRCS depicted in fig. 4D. More specifically, the non-circular cross-section NRCS changes to another cross-sectional portion ACSP as shown. As depicted in fig. 4D, the other cutaway portion comprises a rectangular cross-section having a width W2 less than W1 and a height H2 similar to height H1. As an example, height H2 may be equal to height H1. In one embodiment, the further profile portion ACSP has an original profile similar to the profile near the front end of the SC connector.

Likewise, the rear portion RP may have more than one original cross-sectional shape over its length as desired. Further, the rear portion RP may include one or more retention or locking features that alter or modify the profile. For example, the housing 20 may also include a locking feature 20L such that the connector may be secured in an adapter, port, or other suitable device. For example, locking feature 20L may include features of tensor 37059: a groove/shoulder such as shown in fig. 4E and 45, a sector such as shown in the housing 20 of fig. 3, a reverse bayonet such as depicted in fig. 44, or a ramp with a protrusion such as shown in fig. 71. In these examples, the locking feature 20L is advantageously integrated into the housing 20, and requires no additional parts and can be used with any of the disclosed concepts. In some embodiments, the locking feature 20L is a portion subtracted from the original geometry of the rear portion RP, such as a notch in the rounded rear portion RP. Thus, having the locking features integrated into the housing 20 (e.g., monolithically formed as part of the housing) may enable a more dense array of connectors in a complementary arrangement. Furthermore, these locking features integrated into housing 20 are rearward of connector 10. For example, the integral locking feature of the housing 20 is disposed rearward of the at least one groove 20G in which the O-ring is seated. The locking feature 20L is mateable with a feature of a complementary mating device for ensuring mating of the connector 10 with the complementary mating device.

The housing 20 may also have features (such as markings, keys, keyways, etc.) that assist in proper alignment or orientation of the connector with the complementary device without altering the original form factor of the housing disclosed and claimed herein. Additionally, the housing may have other features for securing an optical fit with a complementary device or threads for securing a dust cap. Fig. 2 is a perspective view of the connector 10 having a housing 20 similar to the housing 20 depicted in fig. 4, but further including threads 28 and keying features 20K. Fig. 25 and 26 depict a fiber optic connector similar to fig. 20 with an alternative housing 20A that may be used with any suitable fiber optic connector disclosed herein. The housing 20 also includes keying features 20K. The keying features 20K have predetermined positions relative to the orientation of the housing 20 for aligning the form factor of the housing with the corresponding mating device. For example, the housing 20 or keying feature 20L provides the proper orientation of the connection in an orientation that may be desirable for connectors having angled ferrules. In this embodiment, the keying feature 20K ensures the correct rotational orientation of the connector 10 during insertion and mating with another device.

In this particular embodiment, the housing 20 is unitarily formed; however, other embodiments may have a design where the housing may be formed from one or more components as desired. The housing 20 having multiple components may be assembled by snap-fitting, adhesives, welding, and the like. Illustratively, fig. 39 and 40 depict the housing 20 having multiple components.

Returning to the description of the connector 10 of fig. 3 and its components, fig. 5 is an exploded view of the ferrule-tube assembly 60 shown in the connector 10 of fig. 3. The ferrule tube assembly 60 may have several different configurations than depicted herein and still practice the disclosed concepts. For example, the ferrule subassembly 60 may use a different ferrule carrier 40 such as disclosed or desired while still practicing the disclosed concepts.

The ferrule 30 is part of a ferrule assembly 60. In these embodiments, the opening 21A at the rear end 21 of the housing 20 is sized for receiving a portion of the ferrule tube assembly 60. When assembled, the ferrule tube assembly 60 is configured to cooperate with the housing 20 for preventing rotation of the ferrule tube assembly 60 relative to the housing 20. For example, the ferrule subassembly may have a friction fit or interlocking structure that mates with the passageway 22 of the housing 20 that resists rotation of the ferrule subassembly 60 relative to the housing 20. However, in other embodiments, the ferrule-tube assembly 60 may be freely rotated for adjustment or the like until the ferrule-tube assembly 60 is fixed in position relative to the housing 20, such as by an adhesive or the like.

As depicted in fig. 5, the ferrule tube assembly 60 includes a ferrule carrier and a resilient member 50. Some embodiments of the ferrule tube assembly 60 may omit the resilient member 50 and not bias the ferrule 30 forward. If resilient members 50 are used, the ferrule carrier 40 may also include resilient member pockets 46, as shown. As depicted, the resilient member pocket 46 may be configured for receiving the resilient member 50 in a direction transverse to the longitudinal direction of the ferrule carrier 40 (transverse to the fiber passage) as represented by the arrow.

As shown in fig. 5, the ferrule carrier 40 includes a ferrule carrier back end 41, a ferrule carrier front end 43, and a ferrule carrier passage 42 extending from the ferrule carrier back end 41 to the ferrule carrier front end 43, wherein the ferrule carrier passage 42 includes a fiber flex zone 47. The fiber flex region allows space for the optical fiber 92 to move backward during mating without causing undue optical attenuation. In other words, during mating, ferrule 30 may be pushed slightly rearward, causing optical 92 of cable 90 to deflect and so as to prevent optical attenuation of fiber flexure zone 47 due to allowing fiber movement.

The ferrule carrier 40 may have several different designs. In one embodiment, the ferrule carrier includes a ferrule carrier front end 43, wherein the ferrule carrier front end 43 includes at least one overhang portion, such as shown in fig. 10. Generally, at least one overhang portion extends from the intermediate portion of the ferrule carrier and allows the ferrule 30 to be assembled into the ferrule carrier 40. The at least one first cantilevered portion 43A may also be configured to cooperate with the shell 20 for preventing rotation of the ferrule 39 relative to the shell 20 when the ferrule subassembly 60 is fully seated in the shell 20, and for allowing rotation of the ferrule 30 for adjustment when the ferrule subassembly 60 is not seated in the shell 20. By way of illustration and example, a forward portion of the longitudinal passage 22 of the housing 20 may be sized for a snug fit to a shoulder 43S provided on the ferrule carrier forward end 43 such that one or more of the overhanging portions squeezes the ferrule 30 and prevents rotation or prevents deflection of at least one overhanging portion such that the ferrule 30 is prevented from rotating beyond its desired position. However, the ferrule carrier 40 still allows the ferrule 30 to "float" to a desired degree such that it may be translated, such as in a rearward direction (i.e., z-direction) or X-Y direction, for precise alignment allowing the ferrule to move slightly to a desired position during mating. For example, the ferrule 30 is biased and may "float" on the resilient member.

The use of the ferrule carrier described herein should not be confused with a ferrule holder that secures a conventional ferrule directly to the ferrule holder so that there is not excessive movement between the ferrule and the ferrule holder. Conventional connectors allow the entire assembly of ferrule holder/ferrule to be spring biased. On the other hand, embodiments such as depicted in fig. 3, 7, and 21 allow for floating of a ferrule without the use of a ferrule holder. Further, the use of a socket holder/socket assembly is another component interface where tolerance stack-ups may exist and affect geometry. Accordingly, the connector disclosed herein may omit the expense and manufacturing time required for conventional ferrule holders and the use of conventional ferrule holders.

Fig. 5 depicts a ferrule carrier front end 43 including a first overhang portion 43A and a second overhang portion 43B. Figures 6 and 7 are longitudinal cross-sectional views of the quill assembly 60 of figure 3 showing details of design and assembly. Fig. 8 and 9 are perspective and close-up perspective views, respectively, of the ferrule carrier 40 of fig. 5-7 depicting details of the ferrule carrier.

In this embodiment, at least one of the first or second overhanging portions 43A or 43B may be configured to cooperate with the housing 20 for preventing rotation of the ferrule 30 relative to the housing 20 when the ferrule subassembly 60 is fully seated in the housing 20 and allowing rotation of the ferrule 30 for adjustment when the ferrule subassembly is not seated in the housing 20. As an illustration, the ferrule carrier front end 43 of fig. 5 may be sized to mate with the shell 20 by fitting into the passage 22, which prevents the overhanging portions 43A, 43B from deflecting outward, thereby preventing rotation of the ferrule 30 relative to the ferrule carrier when the ferrule carrier front end 43 is fully seated in the shell 20, as some of the selectively adjustable surfaces 36 of the ferrule 30 (in this case the flat surfaces 36S) mate with the ferrule retention structures 43C of the ferrule carrier 40.

The ferrule tube assembly 60 is assembled by inserting the springs into the ferrule carrier passage in a transverse direction to place the resilient members 50 into the resilient member pockets 46, as shown in fig. 5. The ferrule carrier 40 of fig. 5 allows insertion of the ferrule 30 from the ferrule carrier front end 43 as represented by the arrow. As the ferrule 30 is inserted into the ferrule carrier front end 43, the first and second overhanging portions 43A, 43B are deflected outwardly as indicated by the arrows shown in fig. 6. When the ferrule 30 is seated in the ferrule carrier front end 43, the first and second overhanging portions 43A and 43B spring back toward their original positions to capture the ferrule 30. As best shown in fig. 7 and 9, one of the first and second overhanging portions 43A, 43B includes a ferrule retention structure 43C. Thus, when the first and second cantilevered portions 43A, 43B are prevented from deflecting, the ferrule 30 is prevented from rotating, such as when the ferrule subassembly 60 is fully seated in the housing 20. However, when first and second cantilevered portions 43A, 43B are allowed to deflect outwardly (such as shown in fig. 6), then ferrule 30 may be rotated by any desired angle θ for adjustment.

Further, the back end of the ferrule carrier 40 may have other features as desired to allow for adjustment. For example, the ferrule carrier back end 41 may have a ferrule carrier groove 41G or shoulder for mating with the cable adapter 59, allowing rotation between the two components in incremental or infinite increments as desired and as discussed herein. As examples, the ferrule carrier 40 may include one or more ferrule carrier rotation keys 41K to allow for rotational step increments, or the ferrule carrier 40 may omit the ferrule carrier rotation keys 41K and allow for infinite rotational positions relative to the cable adapter 59, which may be keyed to the back end 21 of the housing 20. The ferrule carrier 40 may be attached to the cable adapter in any suitable manner, such as adhesive, welding, mechanical fit, and the like.

Other embodiments may integrate the ferrule carrier 40 and cable adapter 59 into a single piece. However, the use of a separate cable adapter 59 allows the connector 10 to be adapted to different cables, such as round, flat, different sizes, by selecting only the appropriately sized cable adapter 59 for the desired cable type. In addition, rather than using a conventional boot (boot), the cable adapter may include one or more flexures 59F at the rear portion for providing cable bending stress relief as desired. The flexure as depicted is suitable for flat cables with preferred bending characteristics.

Likewise, the connectors disclosed herein may allow the ferrule 30 to have a small amount of "float" within the ferrule carrier or housing rather than using a ferrule holder as with conventional fiber optic connectors. Conventional connectors mount the ferrule in a fixed position within the ferrule holder, which is then typically biased by a spring. On the other hand, some of the connector designs disclosed by the present application have the resilient member 50 directly biasing the ferrule, which eliminates parts and also allows for greater flexibility in ferrule selection or adjustment. Further, the ferrule may be adjusted relative to the ferrule carrier or housing depending on the connector design. Furthermore, using a conventional connector with a ferrule holder eliminates high precision geometry of the ferrule holder and tolerance stack-up. However, the housing concepts disclosed herein may be used with connectors having ferrule holders such as disclosed in fig. 70-78.

The ferrule retention structure 43C is configured to mate with a geometric shape on the ferrule 30. Specifically, the ferrule 30 depicted in fig. 5 has at least one selectively adjustable surface 36 that cooperates with the ferrule retention structure 43C. The ferrule retention structure 43C is sized to snugly fit to one or more selectively adjustable surfaces 36 of the ferrule 30, as shown in fig. 7. However, when the ferrule carrier 40 is not disposed in the housing 20, the ferrule 30 may be rotated within the ferrule carrier 40 by about an angle θ for optionally adjusting the assembly. The ferrule 30 may have a rounded selectively adjustable surface 36 for infinite adjustment, but this requires a close fit between the ferrule carrier front end 43 and the appropriate portion of the passage 22 of the housing 20. If ferrule 30 uses a selectively adjustable surface 36 comprising a plurality of flat surfaces 36S, the appropriate portion of passage 22 only has to prevent deflection of at least one cantilevered arm so that ferrule 30 is prevented from rotating when fully assembled. Fig. 8 and 9 depict detailed views of the ferrule carrier 40 of fig. 5. As depicted, the first and second overhanging portions 43A, 43B of the ferrule carrier 40 can have a stepped portion forward of the shoulder 43S, enabling robust seating and resisting deflection of the overhanging arms 43A, 43B.

Ferrule 30 may have any suitable number of plurality of flat surfaces 36S as desired. By way of illustration, four planar surfaces 36S effect quadrant adjustment and the other planar surfaces effect finer adjustment in the first level. However, ferrule 30 may have any number of flat surfaces, such as six or eight flat surfaces, as desired to increase the number of steps for adjusting the ferrule. In general, quadrant adjustment is sufficient, and if coupled with a second stage infinite adjustment interface, the connector can be advantageously adjusted to any desired rotational position in a quick and simple manner during manufacturing.

Fig. 10 is a perspective view of an alternative ferrule carrier 40 'that may be used in the ferrule subassembly 60, and fig. 11 and 12 are a partially exploded view and an assembled view, respectively, of the alternative ferrule carrier 40' in the ferrule subassembly 60. This ferrule carrier 40' is similar to the ferrule carrier 40, but has only a first cantilevered arm and requires the loading of the ferrule 30 from a lateral direction like the resilient member 50. The ferrule 30 may still rotate relative to the ferrule carrier 40', but it may require a slightly greater rotational force to deflect the U-shaped portion or translate the ferrule 30 slightly upward to help reduce the rotational force required for rotation.

Fig. 13 and 14 are partial cross-sectional and cross-sectional views, respectively, of the alternative ferrule carrier 40' of fig. 10-12 depicted assembled into the ferrule assembly 60 and disposed in the housing 29 of the fiber optic connector. As depicted, the passageway 22 of the housing 20 may include different geometries for disposing the ferrule tube assembly 60 within the housing and preventing rotation of the ferrule 30 relative to the housing 20 using the alternate ferrule carrier 40'. As depicted, the housing 20 includes a passage 22 located at the inner key 30KI that mates with the U-shaped portion of the alternate ferrule carrier 40'. Thus, the replacement ferrule carrier is prevented from further rotation relative to the outer shell 20.

Fig. 17 is an exploded view of another cable assembly 100 having fiber optic connectors with a different ferrule assembly 60 similar to cable assembly 100 of fig. 2, and fig. 18 is a partially exploded view of cable assembly 100 of fig. 17 with a fiber optic cable attached to ferrule assembly 60. This cable assembly 100 includes a connector 10 having a ferrule carrier 40 unitarily formed with a cable adapter, as depicted. Additionally, cable assembly 100 is similar to cable assembly 100 of fig. 2.

The concepts disclosed herein may be used with other types and designs of connectors. For example, fig. 19-43 and 46-53 disclose a connector in which the ferrule 30 is inserted from the front end 23 of the connector 10. These connector designs are described without a ferrule holder as generally discussed herein, but may be used with a ferrule holder as desired. These connector designs differ from earlier connector designs in that they do not use a ferrule carrier; however, these designs can still be optionally adjusted as desired. Specifically, these connector designs include a ferrule 30 that "floats" relative to the housing 20 and uses different structures to secure the ferrule while achieving ferrule float. Any suitable housing 20as described herein may be used for these connectors, provided they are suitably modified for securing the ferrule 30, as disclosed in more detail below.

Illustratively, fig. 19 and 20 are perspective views of a cable assembly 100 having a housing 20 with a shell similar to that shown by the fiber optic connector of fig. 2, but with a ferrule 30 loaded from a front end 23 of the housing 20 and securing a lateral retention member 140. Fig. 21 is another cable assembly 100 similar to the cable assembly of fig. 19 having a connector with a housing having discontinuous threads on the housing. Fig. 22 is a perspective assembled view of the cable assembly 100 of fig. 21, and fig. 23 is a perspective view of the cable assembly 100 of fig. 22 with the dust cap 70 installed. Fig. 24 is a longitudinal sectional view of the cable assembly 100 of fig. 22 in a vertical direction, and fig. 29 is a longitudinal sectional view of a front portion of the optical fiber connector 100 in a horizontal direction.

Referring to fig. 21, the connector 10 includes a housing 20, a ferrule 30, and a lateral ferrule retention member 140. The housing 20 is similar to the other housings disclosed herein, but also includes an opening 129 in the outer surface transverse to the longitudinal passageway 22 of the housing 20. Opening 129 is sized for receiving transverse ferrule retention member 140 and securing ferrule 30 in a manner that allows for suitable movement such that ferrule 30 may optionally float, as depicted in fig. 24. The connector 10 may also include a strap 69 for securing the cable 90 to the connector as desired.

Fig. 25 is a detailed exploded view of the front end of the cable assembly 100 of fig. 22, and fig. 26 is a cross-sectional view taken at the opening 129 of the housing 20 of fig. 19 showing the transverse ferrule retention member 140 securing the ferrule 30. As depicted in fig. 25, ferrule 30 is loaded into passage 22 of housing 20 from front end 23 and secured by mating of ferrule 30 with lateral ferrule retention features 140, which lateral ferrule retention features 140 are inserted into openings 129 for mating with at least one surface of ferrule 30. Specifically, ferrule 30 is inserted into passageway 22 until a mating surface, such as a ferrule retention structure, is aligned with opening 129 such that transverse ferrule retention member 140 may engage the surface and secure the ferrule. Additionally, at least one surface of the ferrule 30 that cooperates with the lateral ferrule retention feature 140 that serves as a ferrule retention feature is sized relative to the lateral ferrule retention feature such that the ferrule 30 may float. The ferrule retention feature may also be the same feature as the at least one selectively adjustable surface 36.

In this embodiment, the ferrule has at least one selectively adjustable surface 36 such that the ferrule 30 can have at least two rotational orientations relative to the shell 20 (and which acts as a ferrule retention feature). However, the ferrule 30 may have any suitable number of selectively adjustable surfaces 36 such that the ferrule 30 may have a desired number of rotational positions for adjusting the ferrule. As examples, the ferrule may have four, six, eight, or any suitable number of selectively adjustable surfaces 36 as desired. More specifically, longitudinal passageway 22 of housing 20, which extends from rear end 21 to front end 23, also includes an adjustment recess 24 that mates with longitudinal passageway 22. The adjustment pocket 24 allows the ferrule 30 to be rotated or manipulated within the housing as desired. In this embodiment, the lateral ferrule retention member 140 uses a pair of catches 140C disposed on arms of the lateral ferrule retention member 140. The catchment 140C may be a snug fit to a portion (such as a protrusion) of the housing 29 disposed in the housing 129. However, other variations for securing the hub 30 are possible. As an example, fig. 27 and 28 depict a detailed view of an alternative lateral ferrule retention feature 140 having a trap 140C and a cross-sectional view showing the alternative lateral ferrule retention feature 140 for securing the ferrule 130, respectively. As best depicted in fig. 27, a trap 140C is provided on the mid-portion of the arm of this alternative lateral ferrule retention member 140. Thus, the trap 140C mates with a portion of the ferrule 30 as depicted in fig. 28 rather than the housing 20as depicted in fig. 26. Fig. 29 is a cross-sectional view of a portion of the housing 20 where the width of the opening 129 is greater than the width of the lateral ferrule retention member 140 such that the ferrule 30 may float. Fig. 30 is a cross-sectional view depicting adjustment pocket 24 of housing 20 that allows rotational adjustment of ferrule 30 during manufacture for improved optical performance. Specifically, when the lateral ferrule retention member 140 is disengaged, then the ferrule 30 may be rotated relative to the ferrule. As depicted, adjustment pocket 24 allows ferrule 30 to be rotated by a suitable angle θ for optical adjustment to a preferred rotational position, as represented by the arrow. By way of example, the ferrule 30 may be rotated through an angle θ of ± 180 degrees, but other suitable angles are possible.

Fig. 31 and 32 depict an exemplary ferrule 30 having at least one selectively adjustable surface 36. Figure 31 shows a ferrule adjustable to quadrants with four selectively adjustable surfaces 36. In general, the selectively adjustable surface 36 is configured as a flat surface, as shown. More specifically, the selectively adjustable surface 36 is formed by a plurality of flat surfaces that are recessed on the ferrule 30. With the disclosed concept, finer adjustment is possible by having more selectively adjustable surfaces (such as six, eight, ten, or twelve) to provide more rotational positions to secure the ferrule 30. Fig. 32 depicts a ferrule 30, with a selectively adjustable surface 36 disposed adjacent to a freely rotating portion 36A of the ferrule 30, allowing the ferrule to rotate for adjustment during assembly without removing a transverse ferrule retention member 140. By way of explanation, ferrule 30 in fig. 32 may be secured by lateral retention members 140, and when rotational adjustment is required, ferrule 30 may be placed back until free-wheeling portion 36A is aligned with lateral retention members 140, allowing ferrule to rotate in any direction and when a desired rotational position is reached, ferrule 30 is allowed to translate to a forward position where selectively adjustable portion 36 engages and cooperates with lateral ferrule retention members 140 to prevent ferrule 30 from rotating. Thus, the lateral ferrule retention member 140 does not need to be removed from the outer shell 20 for adjustment.

Fig. 33-36 are various views depicting housing 20 of connector 10 of fig. 23 including opening 129 and adjustment pocket 24. As depicted, the housing 20 is similar to other housings and can be modified as needed for a desired housing configuration. For example, while housing 20 depicts discontinuous threads 28 for attaching dust cap 70 (as shown in fig. 23), variations are possible that eliminate the threads and use a push to open the dust cap. Likewise, other variations of the housing 20 are possible, such as changing the mating geometry and using the concepts disclosed by the mating geometry of the housing 20 depicted in fig. 54. Further, the housing 20 may have different retention features or different locking features 20L. In comparison, the housing 20 of fig. 3 includes a locking feature 20L configured as a sector disposed between the rear end 21 and the front end 23, and the locking feature 20L of the housing of fig. 4 is configured by a shoulder. The shoulder includes an enlarged annular portion 126 having a flat surface on the rear side.

By way of example, fig. 37 is a perspective view of another cable assembly 100 having another alternative connector 10 similar to connector 10 of fig. 19, but also including a multi-piece housing 20 including a spout 160. Fig. 38 is a perspective view of cable assembly 100 with dust cap 70, and fig. 39 is an exploded view of cable assembly 100.

As best depicted in fig. 39, the connector 10 includes a housing 20 having a nozzle that fits around a front end 23. In this configuration, the use of a separate nozzle 160 provides more access to the passageway 22 and allows more space and field of view for assembly. Further, the opening 129 is provided in a position covered by the spout 160 such that once the connector is adjusted and the spout 160 is secured, the lateral ferrule retention member is not visible or accessible. The housing 20 of this embodiment also has a different locking feature 20L and aperture 29 than the housing depicted in fig. 33-36. The locking feature 20L is configured as a groove for receiving a clip or other suitable locking feature from a complementary device for holding the connectors in a mated state when secured. This embodiment of the connector also uses a cable adaptor 59 so that the connector can accommodate different cable types by using an appropriately sized cable adaptor for a given cable 90.

Fig. 40 is a front end cross-sectional view of the connector 10 of fig. 37 showing the nozzle 160 attached to the front end of the housing 20, and fig. 41 is a front end view of the housing showing an attachment interface (not numbered), such as a weld interface, disposed on a front portion of the housing 20. As depicted in fig. 40, once the spout 160 is installed, it prevents removal of the lateral ferrule retention member 140. In other words, the lateral ferrule retention member 140 is not visible nor is it accessible once the nosepiece is installed. Thus, once the connector is adjusted and the nozzle is properly installed, the lateral ferrule retention member 140 is tamper-resistant. The attachment interface of the housing provides a surface to which the spout 160 is attached. The spout 160 may be attached in any suitable manner as desired, such as adhesive, friction fit, snap fit, welding, and the like. In one embodiment, spout 160 is formed from a translucent material. The use of a translucent material for spout 160 allows the use of a UV curable epoxy to secure spout 160.

Other variations of connectors using modified housings or other modified components are also possible. Fig. 42 and 43 are perspective and side views of the connector 10 similar to fig. 37 with an alternative housing 20. In this embodiment, housing 20 does not have an offset distance between transition portions TP1-TP 4. In other words, all transition portions TP1-TP4 are aligned. In addition, the housing 20 includes keying features 20K for orienting the connectors for mating. The keying features 20K are keys, but other embodiments may use other suitable structures such as keyways.

Other variations of the housing disclosed herein are also possible, such as having the rear portion RP with other shapes (such as polygonal cross-section PCS) instead of a circular cross-section RCS. The polygonal cross-section may have any suitable number of sides, such as four, five, six, seven or eight, but other suitable numbers of sides are possible. Other variations with the disclosed housing concept are also possible. For example, the housing 20 of the connector may be configured to cooperate with other devices such that the retention or locking feature of the connector is intended to mate with a different device for maintaining an optical connection at the mating interface. As an example, fig. 44 and 45 are perspective views of portions of an alternative housing 20 depicting other locking feature designs. The housing 20 depicted in fig. 44 and 45 may be used with any suitable connector disclosed herein. Likewise, the locking or retention features may be selected with other features such as the keying feature 20K. The keying feature 20K has a predetermined position relative to the orientation of the housing 20 for aligning the connector form factor with a corresponding mating device. Specifically, the housing 20 provides the proper orientation of the connection in an orientation that may be said to be desirable for angled ferrules. In this embodiment, the keying feature 20K is disposed on the centerline of the fiber optic connector 10 and ensures proper rotational orientation during insertion and mating with another device.

The components or features of the connector may be selected as desired to form other variations of the connector. Illustratively, fig. 46 is a perspective view of yet another cable assembly 100 using a connector similar to that of fig. 37 but with a different cable adaptor 59. The connector also has a different type of locking feature 20L than the housing 20 of the connector of fig. 37. Like the cable adaptor 59 of fig. 37, the cable adaptor 59 of this embodiment is fitted into the rear opening 21A of the housing 20. As discussed, the use of a connector with a separate cable adapter 59 allows the connector to be used with different types of cables simply by replacing and selecting the cable adapter appropriate for the desired cable 90. Fig. 47 and 48 are perspective and cross-sectional views, respectively, of the cable adapter 59 of fig. 46. Fig. 49 is a vertical sectional view showing a cable 90 provided in the cable adaptor 59, and fig. 50 is a horizontal sectional view thereof.

Fig. 47A and 48A are perspective and sectional views of another cable adaptor 59 similar to that of fig. 47. As depicted, the cable adapter 59 may include an aperture 59A, a recessed surface 59R, a shoulder 59S, a passageway 59P, and a cable saddle 59C or cable adapter key 59K as desired for any particular embodiment of the cable adapter 59. Generally, the cable adapter 59 includes a passageway 59P from the cable adapter front end 59F to the cable adapter rear end 59R. The passage 59P allows the optics 92 of the cable 90 to pass therethrough. The shoulder 59S allows the cable adapter 59 to fit snugly within the passageway 22 of the housing 20 and prevents wicking or flow of adhesive in front of the shoulder 59S. Any adhesive or epoxy used to secure the cable adapter 59 may surround the recessed surface 59R for forming a sufficient bonding area, and any excess adhesive or epoxy may flow into the aperture 59A. The housing 20 may include one or more ports 29 for injecting epoxy or adhesive, or the adhesive or epoxy may be placed on the cable adapter prior to insertion into the housing. For example, the housing may include two apertures 29 (such as shown in fig. 49) so that air may escape when the adhesive or epoxy is injected. Additionally, the one or more apertures 29 may be aligned with the aperture 59A of the cable adapter such that the adhesive or epoxy also secures the strength member 94 of the cable 90 to the cable adapter 59, which cable adapter 59 is secured to the housing 20, thereby forming a robust cable/connector attachment and also providing a seal at the rear end. The cable saddle 59C is sized and shaped for a particular cable 90 intended to be secured using a cable adapter and appropriate components as appropriate, such as depicted in fig. 50. The rear portion of the cable adapter 59 may have a cable bend relief area, such as a back-off funnel, flexure, or other suitable structure at the entrance to the passageway, for preventing sharp bending of cables attached to the rear of the cable adapter 59. Further, the cable adapter 59 may or may not include a key 59K for mating with a feature of the housing, as desired. The rear portion 59R of the cable adaptor 59 of fig. 47A includes one or more ribs 59RB adapted to receive a boot or overmold on the rear portion 59R. The ribs 59RB facilitate retention of the boot or overmold.

Fig. 51 is a perspective view of another cable assembly 100 in accordance with the disclosed concept, and fig. 52 is an exploded view of the cable assembly 100. The housing 20 of this embodiment is similar to the housings disclosed herein, but also includes a keyed portion 20KP that extends into the transition region TR as shown, although embodiments without the keyed portion 20KP are also possible. The transition region TR of this housing is asymmetrical. In particular, the asymmetric transition region is the threaded portion TP, but other asymmetric geometries are possible as disclosed herein. In this embodiment, the keyed portion 20KP is configured as a recessed key or cut-away portion on the housing 20, such as a recessed key slot or slice on the side of the connector, leaving a D-shape. The keyed portion 20KP extends into the transition region as shown. The keying portion 20KP mates with a keying portion (such as an additive or male portion) in a connection port of a device for preventing insertion of a non-compliant connector into the connection port. While the keying portion 20KP is disposed at about 180 degrees from the at least one locking feature 20L, the keying portion 20KP is disposed at less than 180 degrees from the at least one locking feature 20L. In other embodiments, the keying portion 20KP may be arranged to remove a side or slice of the housing 20 for forming a cut-away portion of the D-shaped cross-section over the length of the keying portion 20KP, rather than the keyway shown.

The internal configuration of the connector 10 of fig. 52 is similar to that of the connector of fig. 70-78, with the ferrule 30 disposed within the ferrule holder 49 and inserted from the front end 23 of the connector 10 and discussed in more detail with respect to these figures. This embodiment also includes a protective cover or overmold 259 disposed on the rear portion 59R of the cable adapter 59, as best shown in fig. 53. In addition, when assembled, a sealing element such as a heat shrink 99 is disposed over the protective cover or overmold 259 as best shown in fig. 54. The sealing element may also be disposed over a portion of the housing 20, as shown. Placing the sealing element over the boot or overmold and a portion of the housing 20 allows the cable jacket to be sealed to the rear of the connector. This may also improve the bending stress relief of the cable assembly.

Fig. 51A is a rear perspective view of another cable assembly having a cable adapter 59, the cable adapter 59 having a flexure 59F for bending stress relief. Fig. 52A and 53A are side and cross-sectional views of the cable assembly of fig. 51A showing the heat shrink 99 before and after installation. As depicted, if the cable adapter 59 uses the flexure 59F, the flexure 59F is substantially aligned with the flat portion of the cable 90 for cable bend relief. Also, the cable adapter 59 may or may have more than one rotational position relative to the housing 20, depending on the manner in which the ends of the components are mated. As depicted in fig. 53A, housing 20 may have a stepped portion at back end 21 for receiving a portion of heat shrink 99 and may cover flexure 59F while also providing other cable bending stress relief.

Other variations of the housing 20 are possible using the connector concepts disclosed herein. Other disclosed connector embodiments include a locking feature 20L integrated into the housing 20; however, other connectors may use the locking feature as a separate and distinct component from the housing 20. While this may require a larger connector footprint or more access space between the connectors, the concept of separate distinct components for the locking feature is also possible. Fig. 54A is a front perspective view of another housing 20 that may be used with the fiber optic connector concepts disclosed herein. In this embodiment, the securing feature is formed on a separate and distinct component from the housing 20. Specifically, the securing feature is provided on a coupling nut 120 that is threaded and rotates about the outer shaft of the outer housing 20 for securing the connector to a complementary device. Additionally, the housing 20 may not have an offset distance between transition portions of the housing 20, such as depicted in this embodiment.

The connectors disclosed herein may be part of other cable assemblies as desired. For example, fig. 55 depicts a distribution cable 100 'having one or more connectors 10 on a tether cable 90' extending from a mid-span access 93 of the distribution cable. Of course, other suitable components may use connectors according to the concepts disclosed herein.

As an example, the connectors disclosed herein may be converted from a first connector footprint to a second connector footprint. Fig. 56 is a perspective view of an exemplary connector 10 ' further including a transition housing attached around housing 20 for changing connector 10 ' from a first connector footprint to a second connector footprint, and fig. 57 is a cross-sectional view of connector 10 '. As an example, the connector 10' may have a first connector footprint such as that shown in fig. 19, and may be changed to a second connector footprint such as an SC connector by adding a conversion housing 80. However, any suitable connector disclosed herein may be converted as described herein. The conversion housing 80 cooperates with the housing 20 for changing from a first connector footprint to a second connector footprint. In this embodiment, the changing of the first connector footprint to the second connector footprint includes using a single component.

In other embodiments, the changing of the first connector footprint to the second connector footprint includes using a plurality of components. Illustratively, fig. 58 is a partially exploded view of another connector 100 'that can be changed from a cable assembly 100 having a first connector footprint 10 to a second connector footprint 10' as shown in fig. 59. Furthermore, this embodiment of the second connector footprint 10' comprises a hardened connector footprint. Hardened connector footprint means that the connector is suitable for an outdoor environment without protection within the enclosure. Any suitable connector 10 disclosed herein may be used for this transition from the first placement to the second footprint. Fig. 58 depicts cable assembly 100 with connector 10, wherein the plurality of components for transitioning to the second footprint are broken down for depicting assembly of the components. In this particular embodiment, the plurality of components are adapted to convert the connector 10 to a hardened state

A compatible connector; however, the plurality of components may be configured for converting the connector 10 into other hardened connectors as desired. In this embodiment, the plurality of components for conversion into a hardened connector include an inner shroud 83, an outer shroud 87, a conversion housing 82 configured as a shroud, a retaining member 84 configured to retain a nut, and a coupling nut 85. To make the transition to the hardened connector, the inner boot 83 is slid upward over a portion of the connector 10 and the transition housing or boot 82 is slid back into place, and then the retaining nut 84 is secured to the threads of the connector 10. The coupling nut 85 is slid into the shield 82,the outer shroud 87 can then be slid into place from the rear upwards. The shield 82 may include an O-ring 86 for sealing during mating. Fig. 60 is an assembled view of the fiber optic connector of fig. 58 showing a second hardened connector footprint upon which the dust cap 88 is mounted. Fig. 61 is a cross-sectional view of the hardened connector of fig. 60.

Other embodiments of transitions for the connector 10 are possible in accordance with the concepts disclosed herein. By way of example, a connector 10 having a transition region TR with a threaded portion TP similar to the connector 10 of fig. 2A may be converted to another connector. Fig. 62 depicts a cable assembly 100 having a connector 10 in which the connector housing 20 includes a transition region TR having a threaded portion TP, similar to the connector 10 of fig. 2A. Fig. 63 shows the connector 10 of fig. 62 with the conversion housing 82 attached around the housing 20 for changing the first connector footprint connector 10 to a second connector footprint connector 10 ". The second connector footprint of the connector 10 "includes a hardened connector footprint, thereby converting the cable assembly 100 into the cable assembly 100".

Fig. 64 shows a partially exploded view of the connector 10 "of fig. 63. This particular conversion uses for converting the connector 10 to hardened

A plurality of components of the compatible connector 10 "; however, the plurality of components may be configured for converting the connector 10 into other hardened connectors as desired. The components for conversion into the hardened connector 10 "include a conversion housing 82 configured as a shroud, a retaining member 84 configured as a retaining clip, and a coupling nut 85. The shield 82 may include one or more O-rings 86 for sealing during mating with a complementary device.

To make the transition to connector 10 ", shroud 82 is slid into the passage of coupling nut 85 (as shown) and then slid over connector 10 from the front end. Next, the shield 82 is rotated so that the internal threads 82T of the shield 82, as best shown in FIG. 65, engage the threaded portion TP of the connector 10 until the shield 82 is secured to the connector 10. Thereafter, the retaining member 84 is aligned with the forward end of the shield 82 and then pushed onto the connector 10 until it seats and remains on the housing 20, thereby preventing the shield 82 from backing out of the threaded portion TP of the connector 10, as depicted in fig. 66.

Fig. 67 is a detailed sectional view of the front end of the connector 10 ", showing the holding member 84 fixed to the connector 10, and fig. 68 and 69 are perspective views of the holding member 84. As depicted, the retaining member 84 includes an opening 84O at the front for receiving a portion of the housing 20 therethrough when installed. In addition, the retaining member 84 also has a forward flange 84F that is shaped to conform to the passageway of the shroud 82 such that it can be inserted into and engage the connector 10. The retaining member 84 may also include one or more keyways 84K for allowing the retaining member to slide past the keying feature 20K of the connector 10. Windows 84W disposed on opposite sides of retaining member 84 engage ears 27 of housing 20 for securing retaining member 84 to connector 10. Once installed, the retaining member 84 prevents the shroud 82 from rotating and falling out of the connector 10. The connector 100 "may also include a dust cap 88 as in the connector 10' of fig. 60.

The connector concepts disclosed herein may be used with other connector designs such as connectors that use ferrules disposed in a ferrule holder. Fig. 70-78 disclose a cable assembly 100 including the connector 10. The connector 10 of fig. 70-78 is similar to the other connectors 10 disclosed herein, but has a ferrule 30 inserted from the front end 23 of the connector 10 disposed internally within the ferrule holder 49, as depicted in fig. 75. The housing 20 of the connector 10 of fig. 70-78 is similar to the other housings 20 discussed herein, and the differences will be described and other details will not be repeated for the sake of brevity.

Fig. 70 and 71 are perspective and cross-sectional views, respectively, showing a cable assembly 100 including a connector 10 having a ferrule 30 disposed within a ferrule holder 49, forming a ferrule assembly (not numbered) biased to a forward position by resilient members 50. When assembled, the ferrule subassembly (60) is configured to mate with the housing (20) for preventing rotation of the ferrule subassembly (60) relative to the housing (20), as best shown in fig. 78.

As depicted in fig. 70, the connector 10 is configured such that a conversion housing 80 is attachable to the housing 20 for conversion to an SC connector. Likewise, the connector 10 has a housing 20 similar to the housing 20 depicted in fig. 2A with a transition region TR having a threaded portion TP so that it can be converted into a hardened connector as depicted in fig. 62-69.

Fig. 72-74 are various views of the housing 20 of the connector 10 depicted in fig. 70 and 71. Fig. 72A is a diagram illustrating a locking feature 20L of the housing 20 configured as a ramp (not numbered) with a protrusion (not numbered) as a suitable securing feature for mating with a device. The housing 20 is similar to the housing 20 disclosed herein, but also includes one or more latch arms 20LA disposed in a front portion FP of the housing 20. Further, the front opening of the passageway 22 is sized for allowing the ferrule holder 49 to be inserted from the front end 23 of the housing 20, such as shown in the cross-section of fig. 73. The latch arms 20LA are connected at the front end and cantilevered at the rear end such that they may deflect when the ferrule retainer 49 is inserted and then spring back to retain the ferrule retainer 49 once the ferrule retainer 49 is fully inserted.

Fig. 75 is a partially exploded view of the front end of the connector 10 prior to insertion of the ferrule holder 49 and ferrule 30 into the housing 20. Fig. 76 is a cross-sectional view of the front end of the connector 10 after the ferrule holder 49 and ferrule 30 are inserted into the housing 20 and retained by the latch arm 20 LA. As depicted, the latch arms 20LA have a ramp portion for assisting portions of the ferrule holder 49 in deflecting the latch arms 20LA outward when the ferrule holder 49 is inserted into the housing 20, yet spring back on the ferrule holder 49 for retaining same.

Referring to fig. 75, optical fibers 92 of cable 90 are assembled to extend through front end 23 and resilient member 50 is threaded around optical fibers 92, and ferrule holder 49 and ferrule 30 are then threaded over optical fibers 92. When the ferrule holder 49 is inserted into the housing 20, the optical fibers 92 may be clamped in a suitable manner by the holes 20C disposed on opposite sides of the housing 20, as represented by the arrows in fig. 76. Gripping the optical fiber 92 prevents the optical fiber 92 from pushing or flexing backwards when the ferrule holder 49 is inserted. The ferrule holder 49 is aligned to the proper rotational position and pushed back into the housing 20 until retained by the latch arm 20LA, as depicted in fig. 76. The optical fiber 92 is secured to the ferrule 30 in a suitable manner, and the end face of the ferrule 30 is polished.

Additionally, the ferrule holder 49 may be configured for adjusting the ferrule 30 relative to the housing 20. Fig. 77 is a detailed perspective view of a ferrule 30 disposed in the ferrule holder 49. As shown, ferrule holder 49 includes a plurality of recesses 49R formed in flange 49F for adjusting the connector. In this embodiment, the flange 49F has four recesses 49R that enable four different rotational positions of the ferrule holder 49/ferrule 30, thereby enabling quadrant adjustment. Fig. 78 is a detailed front end view of the connector 10 showing the front opening of the housing 20 sized for ferrule holder insertion. In addition, a portion of the passageway 22 is sized to mate with the flange 49F and achieve different rotational positions. Thus, after measuring the end profile of the ferrule 30 or measuring the insertion loss, the ferrule 30 may be adjusted as needed for improved performance, such as according to the class B standard. Illustratively, the latch arm 20LA may be deflected outward to release the ferrule retainer 49, and then the ferrule retainer 49 is rotated to a desired position and inserted back into the housing 20 until it is retained by the latch arm 20 LA. Other embodiments of ferrule holder 49 may have other suitable numbers of rotational positions as desired.

The concepts of the connector housings disclosed herein may also be used with multi-fiber connectors. By way of example, fig. 79 is an assembled perspective view of a cable assembly 300 including a multi-fiber connector 200 having a housing 220. The housing 220 is similar to the housing 20 disclosed herein, including a rear end (221) and a front end (223), wherein a longitudinal passageway (222) extends from the rear end (221) to the front end (223); the housing 220 comprises a portion of the Rear Portion (RP) having a circular cross-section (RCS) and a portion of the Front Portion (FP) having a non-circular cross-section (NRCS). By way of illustration, the Front Portion (FP) may have a rectangular cross-section with Rounded Sides (RS) that provides the connector with a first orientation feature for aligning and preventing insertion into a non-compliant device or port during mating, as best shown in fig. 93.

The housing 220 also includes a Transition Region (TR) disposed between the Rear Portion (RP) and the Front Portion (FP), as best shown in fig. 92 and 93. The Transition Region (TR) of the housing 220 includes a threaded portion TP, as with the other housings 20 disclosed herein. The housing 220 also includes a locking feature 20L integrally formed in the housing 220, as best shown in fig. 92. Fig. 80 depicts that the multi-fiber connector 200 may use a dust cap 280 attached for protecting the ferrule 230 from dust, debris, etc. when unconnected. As with other embodiments disclosed herein, the dust cap 280 may be configured for attachment to the housing 220 using a Threaded Portion (TP).

Fig. 81 depicts an exploded view of a cable assembly 300 having a multi-fiber connector 200. As depicted, connector 200 includes housing 220, multi-fiber ferrule 230, ferrule retainer 249, ferrule retainer 245, resilient member 250, cable adapter 259, and nozzle 260. The connector may include other components, such as one or more O-rings 65 that fit over the housing 220. The connector 200 may have other components, arrangements or configurations depending on various factors such as cabling or other considerations. Cable 90 is similar to the other cables disclosed herein, but it has a plurality of optical fibers. Cable assembly 300 may use any suitable cable design.

Fig. 82-93 illustrate details and construction of the cable assembly 300. FIGS. 82 and 83 are detailed exploded and assembled views, respectively, illustrating the pre-assembly prior to threading the fiber optic cable through pre-assembly of the components of the multi-fiber connector of FIG. 79; the preassembly includes ferrule retainer 249, ferrule retainer 245, resilient member 250, and cable adapter 259. Ferrule retainer 245 includes an aperture 245A sized to receive a portion of ferrule retainer 249 therethrough when attached to cable adapter 259, as shown in fig. 83. Ferrule holder retainer 245 also includes one or more attachment features 245W for securing ferrule holder retainer 245 to a front portion of cable adapter 259. Cable adapter 259 includes a passage 259P from the rear end to the front end for receiving optical fiber 92 therethrough. The opening at the front end of the cable adapter 250 is sized for receiving the resilient member 250 and has a backstop for seating the resilient member 250. When ferrule retainer 245 is attached to cable adapter 259, resilient member 250 biases ferrule retainer 249 to the forward position. Attachment features 245W of ferrule holder retainer 245 mate with attachment features 259F (such as protrusions of cable adapter 259) for securing ferrule holder retainer 245. As depicted in fig. 83, a forward portion of the cable adapter 259 is exposed between the arms of the ferrule holder retainer 245, and a forward portion of the ferrule holder 249 having a recessed portion 249R is exposed. Cable adapter 250 may also include a strain relief 259S for inhibiting sharp cable bends near connector 200.

Fig. 84 is a perspective view showing a cable 90 prepared for insertion into the preassembly of fig. 83, with the appropriate length of strength members 94 and optical fibers 92 exposed. Fig. 83 and 86 depict perspective and cross-sectional views, respectively, of a cable 90 that is threaded through the preassembly of fig. 83 such that an optical fiber 92 extends far beyond the ferrule holder 249. As depicted, cable adapter 259 has holes on opposite sides such that strength members 94 extend through the holes and into grooves 259G of cable adapter 259. An adhesive or other fastener may be applied to the strength members 94 to secure them to the cable adapter 259. FIG. 87 depicts a detailed perspective view of the assembly of FIG. 83 after a portion of the coating of the optical fibers 92 is removed in preparation for inserting the ends of the optical fibers 92 into the multi-fiber ferrule 230. Waiting for the coating to be stripped from the optical fibers 92 until this point in the assembly provides protection for the optical fibers 92 until it is ready to be inserted into the multifiber ferrule 230.

Fig. 88 and 89 show a multi-fiber ferrule 230 attached to an optical fiber 92 and a rear end of the multi-fiber ferrule 230 seated into a recess 249R of a ferrule holder 249. The multi-fiber ferrule 230 may be an MPO ferrule, but other types of ferrules are possible, such as an MT ferrule. Optical fibers 92 are attached to a plurality of fiber holes (232) of multi-fiber 230 in a suitable manner known in the art, such as an adhesive or the like. Fig. 90 shows the housing 220 aligned with the cable adapter 259 prior to attachment. The housing 220 may include any suitable locking feature 20L disclosed herein.

Fig. 92 and 92 show perspective and cross-sectional views, respectively, of a multi-fiber connector prior to attachment to the cable adapter 259. The optical fibers 92 extend beyond the front of the multi-fiber ferrule 230 so that they can be cleaved and polished before the multi-fiber ferrule is stabilized by the housing 220, as shown in fig. 92. As depicted, the openings 229 are aligned over the grooves of the cable adapter 259 so that adhesive can be injected into the openings 29 and wick between the components around the cavity and also contact the strength members 94. A second opening 229 is also provided in the housing 220 so that air may escape when the adhesive is injected. Fig. 93 depicts a perspective view of the assembled multi-fiber connector after the nosepiece 260 is attached to the housing 220. As with the other nozzles disclosed herein, the nozzle 260 may be attached in a similar manner. Such as adhesives, welding, and/or mechanical means (such as mating windows and tabs).

Other variations of the housing 220 in accordance with the disclosed concepts are also possible. As an example of another housing for use with a multi-fiber connector, the housing may be defined as including a portion of a Rear Portion (RP) having a polygonal cross-section (PCS) and a portion of a front portion having a non-circular cross-section (NRCS). The Front Portion (FP) or Rear Portion (RP) of the exemplary housing may also be defined in various configurations as disclosed herein while maintaining a portion of the Rear Portion (RP) having a polygonal cross-section (PCS) and a portion of the Front Portion (FP) having a non-circular cross-section (NRCS). As examples, the polygonal cross-section (PCS) may be hexagonal, square, or any other suitable polygon as desired. Likewise, the complementary device or port would be configured to mate with the housing in a suitable manner.

Other variations of the housing 20 of the connector 10 are also possible. Fig. 94 and 94A depict perspective and cross-sectional views of another connector housing that may be used with any of the disclosed suitable concepts. In this embodiment, the rear portion RP is non-circular and has a polygonal cross-section PCS, as shown in cross-section in fig. 94A. Fig. 94A shows that this housing 20 may have a keying feature 20K, which keying feature 20K may take any suitable form as desired or may be a keying portion 20 KP. Likewise, any suitable locking feature 20L may be used with this housing 20, as desired.

While the present disclosure has been shown and described with reference to exemplary embodiments and specific examples thereof, it will be apparent to those of ordinary skill in the art that other embodiments and examples may perform similar functions and/or achieve similar results. All such equivalent embodiments and examples are within the spirit and scope of the present disclosure and are intended to be covered by the following claims. It will also be apparent to those skilled in the art that various modifications and variations can be made to the disclosed concept without departing from the spirit and scope of the invention. It is therefore intended that the present application also provide such modifications and variations as come within the scope of the appended claims and their equivalents.

Claims (72)

1. An optical fiber connector (10), the optical fiber connector comprising: a housing (20) comprising a rear end (21) and a front end (23), wherein a longitudinal passage (22) extends from the rear end (21) to the front end (23), the housing (21) 20) comprising a front part (FP) and a rear part (RP), wherein the rear part (RP) of the housing (20) comprises a keying part (20KP) and is integrally formed in the housing (20) at least one locking feature (20L) in said rear portion (RP) of ; and A ferrule (30) includes at least one optical fiber hole (32). 2. The fiber optic connector of claim 1, wherein the keying portion (KP) comprises a female key. 3. An optical fiber connector (10), the optical fiber connector comprising: a housing (20) comprising a rear end (21) and a front end (23), wherein a longitudinal passage (22) extends from the rear end (21) to the front end (23), the housing (21) 20) Comprising a front part (FP) and a rear part (RP), wherein the rear part (RP) of the housing (20) comprises a female key and is integrally formed in the rear of the housing (20) at least one locking feature (20L) in the portion (RP); and A ferrule (30) includes at least one optical fiber hole (32). 4. The fiber optic connector of any one of claims 1 to 3, wherein the at least one locking feature (20L) is positioned approximately 180 degrees from the keyed portion (20KP) or the female key . 5. The fiber optic connector of any one of claims 1 to 4, wherein the at least one locking feature (20L) is positioned less than 180 degrees from the keyed portion (20KP) or the female key . 6. A fiber optic connector comprising: a housing (20) comprising a rear end (21) and a front end (23), wherein a longitudinal passage (22) extends from the rear end (21) to the front end (23), the housing (21) 20) Comprising a front part (FP) and a rear part (RP), wherein the rear part (RP) of the housing (20) comprises a female key and is integrally formed in the rear of the housing (20) at least one locking feature (20L) in the top portion (RP), and the at least one locking feature (20L) is positioned approximately 180 degrees from the female key; and A ferrule (30) includes at least one optical fiber hole (32). 7. The fiber optic connector according to any one of claims 1 to 6, wherein the housing (20) further comprises the front part (FP) and the rear part provided on the housing (20) Transition region (TR) between sections (RP). 8. The fiber optic connector of claims 1 to 7, wherein the keyed portion (20KP) or the female key extends into the transition region (TR). 9. A fiber optic connector comprising: a housing (20) comprising a rear end (21) and a front end (23), wherein a longitudinal passage (22) extends from the rear end (21) to the front end (23), the housing (21) 20) comprising a front part (FP), a rear part (RP) and a transition region (TR) provided between said front part (FP) and said rear part (RP) of said housing (20) ), wherein the rear portion (RP) of the housing (20) includes a keyed portion (20KP) extending into a portion of the transition region (TR) and a portion integrally formed in the housing (20) at least one locking feature (20L) in said rear portion (RP), and said at least one locking feature (20L) is positioned approximately 180 degrees from said keyed portion (20KP); and A ferrule (30) includes at least one optical fiber hole (32). 10. The fiber optic connector of any one of claims 7 to 9, wherein the transition region (TR) comprises a threaded portion (TP). 11. The fiber optic connector of any one of claims 7 to 9, wherein the transition region (TR) comprises a first transition portion (TP1 ) provided on a first side of the housing (20) and A second transition portion (TP2) provided on the second side of the housing (20), wherein the first transition portion (TP1 ) and the second transition portion (TP2) are spaced offset in the longitudinal direction distance (OD). 12. The fiber optic connector of claim 11, wherein the first transition portion (TP1) comprises a first riser dimension (FRD) from a non-circular cross-section (NRCS) to a circular cross-section (RCS), and The second transition portion (TP2) includes a second riser dimension (SRD) from the non-circular cross-section (NRCS) to the circular cross-section (RCS), wherein the first riser dimension (FRD) Different from the second riser dimension (SRD). 13. A fiber optic connector comprising: a housing (20) comprising a rear end (21) and a front end (23), wherein a longitudinal passage (22) extends from the rear end (21) to the front end (23), the housing (21) 20) comprising a front part (FP), a rear part (RP) and a transition region (TR) provided between said front part (FP) and said rear part (RP) of said housing (20) ), wherein said rear portion (RP) of said housing includes a recessed key extending into a portion of said transition region (TR) and said rear portion (RP) integrally formed in said housing (20) at least one locking feature (20L) in the transition region (TR) comprising a threaded portion (TP), and the at least one locking feature (20L) is disposed at about 180 degrees from the female key; and A ferrule (30) includes at least one optical fiber hole (32). 14. The fiber optic connector of any of claims 1 to 13, wherein the at least one locking feature (20L) comprises a first locking feature and a second locking feature. 15. The fiber optic connector of any one of claims 1 to 14, further comprising a ferrule holder (49), and wherein the ferrule (30) is provided at the ferrule holder (49) to form a socket tube subassembly (60). 16. The fiber optic connector of claim 15, wherein the opening at the front end (23) of the housing (20) is sized for receiving a portion of the ferrule subassembly (60). 17. The fiber optic connector of claim 15 or 16, wherein the ferrule subassembly (60) is configured to cooperate with the housing (20) for preventing the ferrule subassembly (60) from opposing on the rotation of the housing (20). 18. The fiber optic connector of claim 17, wherein the longitudinal passageway (22) includes an angular stop geometry (20AS) for blocking the ferrule holder (49) relative to the housing (20) ) of the rotation. 19. The fiber optic connector of any one of claims 15 to 18, wherein the housing (20) further comprises one or more latch arms (20LA) for securing the ferrule holder (49) ). 20. The fiber optic connector of any one of claims 15 to 19, further comprising a resilient member (50) for biasing the ferrule holder (49) to a forward position. 21. The fiber optic connector of any one of claims 1 to 14, wherein the ferrule (30) is part of a ferrule subassembly (60), and the rear end of the housing (20) The opening (21a) at (21) is sized for receiving a portion of the ferrule subassembly (60). 22. The fiber optic connector of claim 21, wherein the ferrule subassembly (60) comprises a ferrule carrier (40). 23. The fiber optic connector of claim 22, further comprising a resilient member (50), and wherein the ferrule carrier (40) further comprises a resilient member pocket (46). 24. The fiber optic connector of claim 22 or 23, wherein the ferrule carrier (40) comprises a ferrule carrier front end (43), the ferrule carrier front end (43) comprising a first overhang Section (43a). 25. The fiber optic connector of claim 22 or 23, wherein the ferrule carrier (40) comprises a ferrule carrier front end (43), the ferrule carrier front end (43) comprising a first overhang part (43a) and second overhanging part (43b). 26. The fiber optic connector of claim 24 or 25, wherein the first overhang (43a) is configured for mating with the housing (20) for use when the ferrule subassembly (60) prevents rotation of the ferrule (30) relative to the housing (20) when fully seated in the housing (20). 27. The fiber optic connector of any one of claims 21 to 26, wherein the ferrule subassembly (60) includes a ferrule retention structure (43C). 28. The fiber optic connector of any one of claims 1 to 14, wherein the ferrule (30) has a cooperating with the adjustment recess (24) of the housing to allow rotation of the ferrule with at least one selectively adjustable surface (36) for optical adjustment. 29. The fiber optic connector of claim 28, wherein the selectively adjustable surface (36) of the ferrule (30) is positioned adjacent to a freely rotating portion of the ferrule (30), allowing all Rotation of the socket (30) for adjustment during assembly. 30. The fiber optic connector of claim 28 or 29, further comprising a transverse ferrule retention member (140) for limiting movement of the ferrule (30) relative to the housing (20). 31. The fiber optic connector of claim 30, wherein the housing (20) includes an opening (129) in an outer surface transverse to the longitudinal passage (22). 32. The fiber optic connector of claim 30 or 31, wherein the transverse ferrule retention member (140) comprises a clip. 33. The fiber optic connector of any of claims 28 to 32, further comprising a nozzle (260). 34. The fiber optic connector of any one of claims 28 to 33, further comprising a resilient member (50). 35. The fiber optic connector of any one of claims 1 to 34, wherein the at least one locking feature (20L) is a notch comprising a retention surface (20LRS) formed in the housing (20) . 36. The fiber optic connector of any one of claims 1 to 34, wherein the at least one locking feature (20L) is a notch, groove, shoulder or sector formed in the housing (20) pieces. 37. The fiber optic connector of claim 35 or 36, wherein the at least one locking feature (20L) provides a predetermined retention force of 50 pounds or more. 38. The fiber optic connector of any one of claims 1 to 11 or 13 to 17, wherein a portion of the rear portion (RP) of the housing (220) comprises a circular cross-section (RCS) and A portion of the front portion (FP) of the housing (220) includes a non-circular cross-section (NRCS). 39. The fiber optic connector of any one of claims 10 or 13 to 17, wherein a portion of the rear portion (RP) of the housing (220) comprises a circular cross-section (RCS) and the housing A portion of the front portion (FP) of (220) includes a non-circular profile (NRCS), and wherein the threaded portion (TP) extends from the non-circular profile (NRCS) to the circular profile ( RCS). 40. The fiber optic connector of any one of claims 1 to 39, further comprising a male key (20K). 41. The fiber optic connector of claim 40, wherein the male key (20K) is aligned with the female key. 42. The fiber optic connector of any one of claims 1 to 27 and 34 to 41, wherein the ferrule subassembly (30) is adjustable relative to the housing (20). 43. The fiber optic connector of any one of claims 1 to 27 and 38 to 41, wherein the ferrule (20) comprises a multi-fiber ferrule. 44. The fiber optic connector of any one of claims 1 to 43, wherein the front part (FP) of the housing (20) comprises another cross-sectional part (ACSP). 45. The fiber optic connector of claim 44, wherein the other cross-sectional portion (ACSP) comprises an SC footprint or an SC compatible footprint. 46. The fiber optic connector of any one of claims 1 to 45, further comprising a cable adapter (59). 47. The fiber optic connector of any one of claims 1 to 45, further comprising a shield attached to the cable adapter (59). 48. The fiber optic connector of any one of claims 1 to 45, further comprising a shield overmolded on the cable adapter (59). 49. The fiber optic connector of claim 47 or 48, further comprising a sealing element disposed around a portion of the shield and a portion of the rear portion (RP). 50. The fiber optic connector of any one of claims 46 to 49, wherein the cable adapter (59) receives a portion of a resilient member (250) and a portion of a ferrule retainer (249), and the ferrule retains A retainer (245) is attached to the cable adapter (59). 51. The fiber optic connector of claim 46, wherein the cable adapter (259) includes a strain relief portion (259S). 52. The fiber optic connector of any one of claims 1 to 51, further comprising an O-ring (65). 53. The fiber optic connector of claim 52, wherein the O-ring (65) is disposed behind the at least one locking feature (20L). 54. The fiber optic connector of any one of claims 1 to 53, further comprising a dust cap (280). 55. The fiber optic connector of any one of claims 1 to 54, further comprising a transition housing (80, 82), wherein the transition housing (80, 82) cooperates with the housing (20) for use for changing the optical fiber connector (10) from the first connector footprint to the second connector footprint. 56. The fiber optic connector of claim 55, wherein the second footprint comprises a hardened connector footprint. 57. The fiber optic connector of claim 55, wherein the change from the first connector footprint to the second connector footprint comprises a single component. 58. The fiber optic connector of claim 55, wherein the change from the first connector footprint to the second connector footprint comprises a plurality of components. 59. The fiber optic connector of claim 55 or 57, wherein the second connector footprint is an SC connector footprint or an SC compatible connector footprint. 60. The fiber optic connector of any one of claims 55, 56, or 58, wherein the change from the first connector footprint to the second connector footprint comprises an inner shield, an outer Guards, shrouds, retaining members and coupling nuts. 61. The fiber optic connector of any one of claims 55, 56, 58, or 60, wherein the second connector footprint is

Compatible footprint. 62. The fiber optic connector of any of claims 1 to 61, which is part of a cable assembly (100). 63. The fiber optic connector of any of claims 1 to 61, which is part of a distribution cable (100'). 64. The fiber optic connector of any one of claims 1 to 61, further comprising a fiber optic cable (90) comprising at least one strength element, the at least one of the fiber optic cables A strength element is attached to a portion of the fiber optic connector. 65. A fiber optic connector (10) comprising: a housing (20) comprising a rear end (21) and a front end (23), wherein a longitudinal passage (22) extends from the rear end (21) to the front end (23), and the rear end (23) The end (21) includes a rear opening (21A); A ferrule (30), the ferrule (30) comprising at least one optical fiber hole (32). a cable adapter (59) sized for fitting into said rear opening (21A) of said housing (20); a protective cover attached to the cable adapter; and A sealing element is provided around a portion of the shield and a portion of the rear portion (RP) of the housing. 66. The fiber optic connector of claim 65, wherein the rear portion (RP) of the housing (20) comprises a keyed portion (20KP) and is integrally formed in the rear portion of the housing (20) At least one locking feature (20L) in the portion (RP). 67. The fiber optic connector of claim 66, wherein the keyed portion (KP) comprises a female key. 68. The fiber optic connector of any one of claims 65 to 67, wherein the at least one locking feature (20L) is positioned approximately 180 degrees from the keyed portion (20KP) or the female key . 69. The fiber optic connector of any one of claims 65 to 67, wherein the at least one locking feature (20L) is positioned less than 180 degrees from the keyed portion (20KP) or the female key . 70. The fiber optic connector of any one of claims 65 to 69, wherein the housing (20) further comprises the front part (FP) and the rear part provided on the housing (20) Transition region (TR) between sections (RP). 71. The fiber optic connector of claim 70, wherein the keyed portion (20KP) extends into the transition region (TR). 72. The fiber optic connector of claim 70 or 71, wherein the rear portion (TR) comprises a keyed portion (TP).

Images